RU149927U1 - ELECTRON-OPTICAL IMAGE CONVERTER - Google Patents

Abstract

1. An electron-optical image converter comprising a housing, a translucent photocathode, a focusing electrode, an anode, an accelerating electrode, consisting of two elements, one of which is stationary and made in the form of a hollow body of revolution with holes in the side surface through which holes are inserted into it fixing springs, and the other, equipped with a mesh or slotted diaphragm, is arranged to move inside the first element and fix relative to the photocathode by the said springs, characterized in that The main element of the accelerating electrode is made in the form of a ring fixed on the lever and mounted for movement along an arc around an axis perpendicular to the axial symmetry plane of the stationary element of the accelerating electrode, while the axis of rotation of the moving element is located outside the internal cavity of the stationary element. 2. The electron-optical image converter according to claim 1, characterized in that one of the parts of the housing is simultaneously a focusing electrode, a fixed cylindrical element of the accelerating electrode is installed in front of the glass entrance window, several flat springs are fixed on the outer side surface of the stationary element, the ends of which are through holes are inserted inside the fixed element; the movable element of the accelerating electrode is equipped with a grid and made in the form of a ring with a conical outer lateral surface, mounted on a lever and made to rotate in an arc around an axis located in the groove of the stationary element outside its internal cavity. 3. The image converter is shown

Description

The proposed solution relates to electronic equipment, in particular to devices for recording fast processes, namely, to electron-optical image converters (image intensifiers) [H01J 31/50].

Known image intensifier tube [1], containing a translucent photocathode, an accelerating electrode with a grid, a focusing electrode, an anode, an image scanning system and a luminescent screen. The presence of an electrode with an accelerating grid near the photocathode makes it possible to register fast processes with a picosecond time resolution, but makes it impossible to manufacture the photocathode inside the device, therefore, its photocathode is made in a separate volume, which is then attached to the device and the photocathode is transferred inside the image intensifier tube through a plug, which is subsequently sealed.

The disadvantage of this image intensifier is that when the photocathode is transferred, its sensitivity decreases by about 20% in the visible range, and by several times in the infrared (at a wavelength of about 1000 nm).

Known image intensifier tube [2], also containing a translucent photocathode, an accelerating electrode with a grid, a focusing electrode, an anode, an image scanning system and a luminescent screen. This EOC, which is in its technical essence the prototype of the proposed device, the accelerating electrode is made up of two elements, one of which is a cylinder, on the side surface of which fixing springs are installed, and inside this cylinder there is a second element with a fine-grained mesh, which is also made in the form of a cylinder, installed with the possibility of its movement along the inner cylindrical side surface of the first element and fixing relative to the photocathode by the said springs. In the manufacture of the photocathode inside this IC, the movable element of the accelerating electrode is preliminarily installed at the technological position near the anode, and the evaporators of the photocathode components are inserted through the dams into the instrument shell between the photocathode substrate and the movable element grid. After manufacturing the photocathode, the evaporators are removed from the shell, and the movable element of the accelerating electrode moves to the photocathode, and the device holding the fixing springs is activated, they enter the inner cavity of the first cylinder of the accelerating electrode and fix the movable element at the working position near the photocathode.

The main disadvantage of this image intensifier tube is the high supply voltage required to obtain a picosecond time resolution. This is due to the large length of the cylindrical elements of the accelerating electrode and, accordingly, the electron-optical system as a whole, necessary for placing the movable cylinder of the accelerating electrode at the technological position between the sources of the photocathode components and the anode. Since for reliable, without jamming, movement of one cylindrical surface inside another, it is recommended to choose a ratio of the length of the movable element to its diameter of at least 1.0-1.5, the minimum length of the stationary element of the accelerating electrode should be about two to three of its diameters. Especially taking into account that the details of the image intensifier tube during its processing at the pumping station are heated to a temperature of about 650 ° K, and the movement of the movable element is carried out in vacuum.

In the EOP PV-001 [3], made in accordance with [2], despite the fact that the ratio of the length of the movable element of the accelerating electrode to its diameter is less than 1.0 and, accordingly, the length of the fixed element is reduced to provide a temporary resolution of level 1 ps, a voltage between the photocathode and the anode of 15 kV is required. In this case, a decrease in the length of the movable element of the accelerating electrode has led to the fact that it often gets stuck in an already sealed device when moving inside the stationary one due to a skew in the gap and is not properly set to the working position.

The purpose of the utility model and the technical result is to reduce the supply voltage of the image intensifier tube and ensure reliable movement and installation of the moving element of the accelerating electrode to the working position.

This goal and result is achieved due to the fact that the electron-optical image converter containing a housing, a translucent photocathode, a focusing electrode, an anode, an accelerating electrode, consisting of two elements, one of which is stationary and made in the form of a hollow body of revolution with holes in the lateral surface through which the fixing springs are inserted inside it, and the other, equipped with a mesh or slotted diaphragm, is made with the possibility of moving inside the first element and fixing relative to the photo the anode with said springs, characterized in that the movable element of the accelerating electrode is made in the form of a ring fixed to the lever and mounted to move in an arc around an axis perpendicular to the axial symmetry plane of the stationary element of the accelerating electrode, while the axis of rotation of the moving element is located outside the inner cavity of the fixed element .

Preferably, one of the housing parts is simultaneously a focusing electrode, a fixed cylindrical element of the accelerating electrode is installed in front of the glass entrance window, several flat springs are fixed on the outer side surface of the fixed element, the ends of which are inserted through the holes into the stationary element; the movable element of the accelerating electrode is equipped with a grid and is made in the form of a ring with a conical outer lateral surface, is mounted on a lever and is made to rotate in an arc around an axis located in the groove of the fixed element outside its inner cavity. Preferably, the photocathode is inserted into the shell through an opening in the focusing electrode and is placed in the space between the stationary element of the accelerating electrode and the anode.

The movable element of the accelerating electrode is mounted to move in an arc around an axis perpendicular to the plane of axial symmetry of the stationary element of the accelerating electrode.

Preferably, the outer side surface of the ring of the movable element of the accelerating electrode is made in the form of a spherical belt or a truncated cone, and the minimum distance from the axis of rotation of the movable element of the accelerating electrode to the axis of symmetry of the stationary element of the accelerating electrode satisfies the conditions:

L = H ² (D ∗ -d) ^-1 -0.25 (D ∗ + d)

L = (Hh) ² (D ∗ -D) ^-1 -0.25 (D ∗ + D)

where: H is the distance between the axis of rotation of the movable element and the end face of the stationary element of the accelerating electrode, on which the ring of the movable element is fixed; h is the height of the outer side surface of the ring, and d and D are its smallest and largest diameters; D ∗ is the inner diameter of the fixed element of the accelerating electrode in the cross section, in the plane of which lies the axis of rotation of the movable element, the smallest and largest diameters of the outer side surface of the ring of the movable element satisfy the condition: d <2S <D, where S is the distance between the fixing springs and the axis of symmetry of the stationary element of the accelerating electrode. Brief Description of the Drawings

In FIG. 1 shows a variant of the construction made in accordance with the proposed invention (part of the image intensifier tube with an image scanning system and a luminescent screen is not shown).

In FIG. 2 shows a structure with a movable element of an accelerating electrode mounted in a working position.

Utility Model Implementation

In the shell, one of the parts of which is simultaneously the focusing electrode 1 of the electron-optical image intensifier tube system, a fixed cylindrical element of the accelerating electrode 3 is installed in front of the glass entrance window 2. Several flat springs 4 are fixed on the outer side surface of the fixed element (Fig. 1 shows one at the top ), the ends of which through the holes are inserted inside the stationary element. The movable element of the accelerating electrode equipped with a grid is made in the form of a ring 5 with a conical outer lateral surface, is mounted on a lever 6 and can rotate in an arc around an axis 7 located in the groove of the stationary element outside its internal cavity.

The evaporator is a component of the photocathode 8, introduced into the shell through an opening in the focusing electrode, placed in the space between the stationary element of the accelerating electrode and the anode 9. In FIG. 1 movable element of the accelerating electrode is in the technological position (under the evaporator).

When installing the movable element in the working position, the lever enters the groove of the stationary element and restores its axial symmetry.

The proposed design with the movable element of the accelerating electrode installed in the working position is shown in FIG. 2.

The end surface of the ring of the movable element facing the anode is provided with inclined samples in which the ends of the fixing springs abut, pressing the movable element against the end surface of the fixed element of the accelerating electrode.

Due to the fact that the movable element of the accelerating electrode is made in the form of a ring fixed on the lever and is mounted with the possibility of moving in an arc around an axis perpendicular to the axial symmetry plane of the stationary element of the accelerating electrode, the axis of rotation of the moving element is located outside the internal cavity of the fixed element, in general this provides a reduction in supply voltage and provides reliable movement and installation of a movable element, accelerating the electrode to a working position.

The image intensifier tube is installed at the pumping station as shown in FIG. 1. After the formation of the photocathode, the evaporators of its component are removed from the cavity of the converter, and it is soldered from the post. Then the device is turned down by the input window, accelerated in the same direction and sharply braked. The movable element begins to rotate around the axis. Due to the stored kinetic energy, it unclips the fixing springs with a conical surface of the ring and abuts against the end surface of the fixed element. The springs snap into inclined samples, fixing the movable element in the working position.

At present, an EOF model has been manufactured with the proposed design of an accelerating electrode, which, due to the reduction in the length of the electron-optical system, provides the same temporal resolution as PV-001 at three times lower supply voltage. At the same time, multiple tests confirmed the high reliability of the operation of the mechanism for moving, installing and fixing the movable element of the accelerating electrode at the working position.

Currently, from an analysis of the patent and scientific and technical literature, the applicant company does not know objects in which there are signs that are distinctive in the claimed solution, that is, the technical property of the analyzed object is new (not inherent in known objects, including the analogue). Thus, the property that the supply voltage is reduced and reliable movement and installation of the movable element of the accelerating electrode to a working position is ensured, an object characterized by a set of features in the full volume of the formula, that is, the claimed technical solution is a new set of features, as a combination of known and unknown features and a new technical property, that is, meets the criterion of "significant differences".

Information sources:

1. Butslov M.M., Stepanov B.M. Pulsed electron-optical light amplifiers for studying nanosecond and picosecond light processes. The Journal of Scientific and Applied Photography, vol. 20, 1975, no. 3, p. 198, USSR Academy of Sciences

2. Brukhnevich G.I., Kondrasheva L.I., Lukin V.F., Miller V.A., Smolkin B.D., Stepanov B.M. USSR author's certificate N813533, MKL ³ H01J 31/50, issued 11/14/1980, priority from 01/09/1979, (prototype).

3. Brukhnevich G.I., Miller V.A., Smolkin B.D., Stepanov B.M. New time-analyzing electron-optical converters. "Proceedings of the 14th International Congress on High-Speed Photography and Photonics", Moscow, October 19-24, 1980, p. 170-171.

Claims (5)

1. An electron-optical image converter comprising a housing, a translucent photocathode, a focusing electrode, an anode, an accelerating electrode, consisting of two elements, one of which is stationary and made in the form of a hollow body of revolution with holes in the side surface through which holes are inserted into it fixing springs, and the other, equipped with a mesh or slotted diaphragm, is arranged to move inside the first element and fix relative to the photocathode by the said springs, characterized in that The main element of the accelerating electrode is made in the form of a ring fixed on the lever and mounted for movement along an arc around an axis perpendicular to the axial symmetry plane of the stationary element of the accelerating electrode, while the axis of rotation of the moving element is placed outside the internal cavity of the stationary element. 2. The electron-optical image converter according to claim 1, characterized in that one of the parts of the housing is simultaneously a focusing electrode, a fixed cylindrical element of the accelerating electrode is installed in front of the glass input window, several flat springs are fixed on the outer side surface of the stationary element, the ends which through the holes introduced into the stationary element; the movable element of the accelerating electrode is equipped with a grid and is made in the form of a ring with a conical outer lateral surface, mounted on a lever and made to rotate in an arc around an axis located in the groove of the stationary element outside its internal cavity. 3. The electron-optical image converter according to claim 1, characterized in that the photocathode is inserted into the shell through an opening in the focusing electrode and is placed in the space between the stationary element of the accelerating electrode and the anode. 4. The electron-optical image converter according to claim 1, characterized in that the movable element of the accelerating electrode is mounted to move in an arc around an axis perpendicular to the axial symmetry plane of the stationary element of the accelerating electrode. 5. The electron-optical image converter according to claim 1, characterized in that the outer side surface of the ring of the moving element of the accelerating electrode is made in the form of a spherical belt or a truncated cone, and the minimum distance from the axis of rotation of the moving element of the accelerating electrode to the axis of symmetry of the stationary element of the accelerating electrode satisfies the conditions: L = H ² (D * -d) ^-1 -0.25 (D * + d), L = (Hh) ² (D * -D) ^-1 -0.25 (D * + D), where Η is the distance between the axis of rotation of the movable element and the end face of the stationary element of the accelerating electrode, on which the ring of the movable element is fixed; h is the height of the outer lateral surface of the ring, ad and D are its smallest and largest diameters; D * is the inner diameter of the stationary element of the accelerating electrode in the cross section, in the plane of which lies the axis of rotation of the movable element, while the smallest and largest diameters of the outer side surface of the ring of the movable element satisfy the condition: d <2S <D, where S is the distance between the fixing springs and the axis of symmetry of the stationary element of the accelerating electrode.

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