UA118547U - DEVICES FOR ACTION ON MATERIAL OBJECTS BY ELECTROMAGNETIC EMISSIONS - Google Patents

Abstract

Device for acting on material objects by electromagnetic radiation includes a tubular housing, a microwave generator, an electron accelerator having a cathode and anode, as well as a spherical reflector with an inner mirror surface. It is provided with a series of cylindrical resonator and a concentrator of electromagnetic energy installed in the axis of the metal body, while a microwave generator connected to the electron accelerator in the form of an electronic gun, opposite to the cathode, is placed in front of the cathode. and at the end of the tube, an anode target is mounted, integrated into the electron beam input device into the electron drive, which is covered externally by the magnet system.

Description

A useful model belongs to the technique of generating electromagnetic pulses. Devices for acting on material objects with electromagnetic radiation are of great interest to science and technology. Of particular interest are devices of this type, which have, in addition to high power, compactness, high reliability and autonomy. Such devices can be used in materials science, in particular, to study the mechanisms of destruction of continuous, cracked and multilayered media.

A known device for acting on material objects with electromagnetic radiation, containing an extension electrode and a power source, as well as an additional electrode made in the form of a grid and located along the extension electrode, as well as at least one pre-polarized ferroelectric sample located between the extension electrode and the near an additional electrode to it, and a voltage generator connected to the electrodes through a conductive feeder and a control switch is used as a power source

Russian Patent No. 2187167 НО1ТО25/02, 2002

The use of this device to act on material objects with electromagnetic radiation is characterized by the creation of radiation in a narrow range of the scale of electromagnetic waves.

A known device for acting on material objects with electromagnetic radiation, which includes a tubular body, a microwave generator, an electron accelerator having a cathode and an anode, as well as a spherical reflector with an internal mirror surface. At the same time, the housing in the form of a pipe is vacuumed and made of glass with zigzag-shaped sections, and inside the pipe there are sequentially located: an ion source of electrons, tubular accelerating electrodes, and an anode, which is located at the end of a zigzag section, and a spherical lead reflector with an internal mirror surface focuses radiation on the object | RF Patent 2409798С02, 418 6/00, 2006|.

The use of this device is characterized by a low density of electromagnetic radiation when acting on an object.

The task of this useful model is to improve the device for acting on material objects with electromagnetic radiation by changing the composition of its elements and ensuring their special connection with each other, as a result of which the density of electromagnetic radiation increases

From radiation when acting on an object.

The task is solved due to the fact that the proposed device for acting on material objects with electromagnetic radiation, which includes a tubular body, a microwave generator, an electron accelerator with a cathode and an anode, as well as a spherical reflector with an internal mirror surface, according to the useful model equipped with a cylindrical resonator and a concentrator of electromagnetic energy installed in series along the axis of the body, while in the vacuumed cylindrical resonator there is a microwave generator connected to an electron accelerator in the form of an electron gun, opposite the cathode of which is a flight tube with a magnetic system placed around it, and at the end of the pipe there is an anode-target, built into the device for introducing the electron beam into the electron accumulator, surrounded on the outside by a system of magnets, which is a torus, the beam output from which is connected through a waveguide to an electron beam splitter into two, and each of the separated beams through the glass capillaries of the winding based on a hollow cylindrical tube connected to a funnel and installed in a concentrator, at the end of which a spherical reflector is placed, the funnel itself is connected to a rigid waveguide with an antenna attached to it, and the concentrator itself is fixed in a spherical joint, and the capillaries are wound in two rows - one on top of the other, and the last turns of the capillaries in both rows are closed on themselves, while the device is equipped with a second microwave generator, which is placed in an additional housing, connected through a flexible waveguide to the electron accumulator, and through two other flexible waveguides - with the last turns of glass capillaries.

The difference between the proposed device and the closest analogues is that the device is equipped with a cylindrical resonator and a concentrator of electromagnetic energy installed in series along the axis of the metal housing, while in the evacuated cylindrical resonator there is a microwave generator connected to an electron accelerator in the form of an electron gun, opposite the cathode which has a flight pipe with a magnetic system placed around it, and an anode-target is installed at the end of the pipe, built into the device for introducing the electron beam into the electron accumulator, surrounded on the outside by a system of magnets, which is a torus, the output of the beam from which is connected through a waveguide to an electron beam splitter into two, and each of the split beams is wound through glass capillaries on a hollow cylindrical tube connected to a funnel and installed in a concentrator, at the end of which a spherical reflector is placed, the funnel itself is connected to a rigid waveguide with an attached antenna, and the con the centralizer is fixed in a spherical joint, and the capillaries are wound in two rows - one on top of the other, and the last turns of the capillaries in both rows are closed on themselves, while the device is equipped with a second microwave generator, which is placed in an additional housing, connected through a flexible waveguide with an electron accumulator, and through two other flexible waveguides - with the last turns of glass capillaries.

The technical result of using the proposed device for acting on material objects with electromagnetic radiation, in comparison with the closest analogues, is an increase in the density of electromagnetic radiation when it acts on the object.

This is achieved on the basis of the effect of the formation of non-contact movement of electron clusters in glass capillaries wound on a cylindrical tube in the form of a double row of rings, resulting in a source of electromagnetic radiation in a wide spectral range, which is applied to the irradiated object through the concentrator of the device and through the connected to it funnel with a rigid waveguide, at the end of which there is an antenna.

The essence of the useful model is explained by the drawings, where in Fig. 1 shows the general view of the device for acting on material objects with electromagnetic radiation; in Fig. 2 shows the electron accumulator (top view), in Fig. C - the electron accumulator is also shown (side view).

The device for acting on material objects by electromagnetic radiation contains a tubular metal case 1 with a vacuumed cylindrical resonator 2 placed along the axis of the case, in the cavity of which an electron gun 3 is placed, opposite to which, coaxially with the cover of the resonator, externally connected through a hole in the resonator 2, a flight pipe 4 with a magnetic system 5 placed around it, an anode target 6 is installed at the end of this pipe, built into an electron beam input device 7, connected to an electron accumulator 8 with a magnet system 9, as a power source a high-frequency generator 10 with a communication loop is connected to the resonator 2 11 for adjusting the level of the microwave power introduced into the cylindrical resonator 2, the second microwave generator 12, placed in the additional housing 13 through the strip line 14 using the microwave radiation separator 15, through the flexible waveguide 16 connected to the input 17 of the incoming microwave radiation in the electron accumulator 8, on the output 18 of which is placed the electron beam splitter 19, connected to two glass capillaries 20 and 21, which are wound in two rows - one on top of the other 22 and 23 on a hollow cylindrical tube 24, connected to a spherical joint 25, inserted in the guides 26, and the last turns of the capillaries in the lower 22 and upper rows 23 are closed on themselves, and two flexible microwave waveguides 27 are connected to them. The system of lower 22 and upper turns 23 of capillaries is enclosed in a concentrator 28, at the end of which a microwave radiation reflector 29 is located, the concentrator 28 passes into a funnel 30, at the output of which there is a rigid waveguide 31 equipped with an antenna 32.

The operation of the device for acting on material objects with electromagnetic radiation is carried out as follows. From the microwave generator 10 through the communication loop 11 into the cylindrical resonator 2, placed along the axis of the housing 1, microwave power is supplied, while the voltage of ultra-high frequency oscillations appears. When the electron gun Z is turned on, an electron flow is emitted from it, which is accelerated in the resonator 2 and the flight tube 4, focused using the magnetic system 5, to the target anode b, then the electron flow passes through the electron beam introduction device 7 and enters the electron accumulator 8. in which, moving in a circle, the flow of electrons rotates in a closed ring under the influence of the Lorentz force caused by the influence of permanent magnets U. Simultaneously with the inclusion of the microwave generator 10, the microwave generator 12 is turned on, which is located in the additional housing 13 and the power regulation in which is carried out similarly, as in the microwave generator 10. The voltage of ultra-high-frequency oscillations that appeared spreads along the strip line 14, from which, through the microwave radiation separator 15 with the help of a flexible waveguide 16, the microwave radiation is introduced into the input device 17, built into the closed electron storage ring 8, as a result of which the energy modulation of the particles by the field c begins of a weak wave, and as a result, electrons with changed energies collect by inertia into clumps, the distance between which is equal to the wavelength. Thus, clumps are formed from an initially homogeneous electron beam in a self-consistent process that occurs in the space of electron-wave interaction. During this process, the electron storage device is closed, a negative pulse from the high-frequency generator 10 is supplied to the input of the electron beam output device 18. After a given time interval, the control system supplies a positive pulse to the input of the electron beam output device 18, and the electron storage device 8 opens, further formed the electron bunches enter the electron beam splitter 19 through flexible 60 glass capillaries 20 and 21 are fed to the lower 22 and upper 23 series of rings fitted on the cylindrical tube 24. The microwave power from the microwave generator 12 is supplied through flexible microwave separators 27 in the last, self-closed capillary rings of the lower 22 and upper row 23. Thus, the electromagnetic wave propagates toward the formed electron clusters. This process, in which charges oscillate with one wave and then emit a wave of a second frequency, occurs because the reflected photon has much more energy than the incident one. Bunches of electrons, rocked by an electromagnetic wave directed towards this flow along the rings of glass capillaries of the lower 22 and upper row 23, emit electromagnetic waves as a result of centripetal acceleration acting on the flow of electrons in the capillary rings, and the radiation is directed perpendicular to the plane of rotation of the electron back and forth . In order to avoid losses of electromagnetic radiation, two rows of capillaries 22 and 23 are placed in the concentrator 28, at the end of which there is a microwave radiation reflector 29, which directs an ultra-high frequency pulse in a given direction. As a result, the electromagnetic radiation passes from the concentrator 28 into the funnel 30 and then passes into the rigid waveguide 31, equipped with an antenna 32, which directs the radiation to the given object. The emitter is aimed at the object using the spherical joint 25 located in the guiding device 26. By giving the command to activate the spherical joint 25, the control system allows moving the pipe 24 attached to the joint with two rows of lower and upper capillaries 22 placed on it and 23, enclosed in the concentrator 28, which passes into the funnel 30 and further into the rigid waveguide 31 with the antenna 32 placed on it, to any given point.

Thus, during the operation of the device, due to the formation of non-contact movement of electron clusters in its specified elements, a source of electromagnetic radiation appears, the density of which when acting on the object is approximately 3 times higher, compared to the closest analogues. At the same time, high accuracy of the action of electromagnetic radiation on the object is ensured.

Claims (1)

FORMULA OF A USEFUL MODEL A device for acting on material objects by electromagnetic radiation, which includes a Zo tubular body, a microwave generator, an electron accelerator having a cathode and an anode, and a spherical reflector with an internal mirror surface, which is characterized by the fact that it is provided with a serially installed along the axis of the metal body with a cylindrical resonator and a concentrator of electromagnetic energy, while in the vacuumed cylindrical resonator there is a microwave generator connected to an electron accelerator in the form of an electron gun, opposite the cathode of which is a flight tube with a magnetic system placed around it, and at the end of the tube is installed the target anode, built into the device for introducing the electron beam into the electron accumulator, is surrounded by a system of magnets, which is a torus, the beam output from which is connected through a waveguide to the separator of the electron beam into two, and each of the separated beams is wound through glass capillaries on hollow cylinder tube connected to the funnel and installed in the concentrator, at the end of which a spherical reflector is placed, the funnel itself is connected to a rigid waveguide with an antenna attached to it, and the concentrator itself is fixed in a spherical joint, and the capillaries are wound in two rows - one on top of one another, and the last turns of the capillaries in both rows close on themselves, while the device is equipped with a second microwave generator, which is placed in an additional housing, connected through a flexible waveguide to the electron accumulator, and through two other flexible waveguides - to the last turns glass capillaries.