RU2687291C1 - Method of creating a directed ionizing channel in air - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to methods of creating a directed ionizing channel in air and can be used to create devices for scientific research in the field of electricity, in particular for producing gas-discharge plasma in air and analyzing its properties. Device for obtaining a directed ionizing channel in air is electron-beam tube 1 (Fig. 1) and an electrostatic field source, which can be electrostatic machine 2 (Fig. 1). Method of creating a directional ionizing channel in air is carried out as follows. To electron-beam tube 1 (Fig. 1) power supply unit 3 (Fig. 1), which provides operation of electron-beam tube. On the opposite side from the power supply unit to the screen of the cathode-ray tube there connected is metal tube 4 (Fig. 1), which can be made of stainless steel, nickel, aluminum or copper and inside which there is porous material, which, in turn, can be made of ceramic filter 5 (Fig. 1), and before placing ceramic filter into metal tube, filter is impregnated with aqueous solution of heteropolyacid 1–12 of row, having chemical formula H₆[PW₁₀V₂O₄₀], with concentration from 45 to 75 %. After that, the filter is dried for 4–7 hours in a drying cabinet in the temperature range from 30 to 50 °C. Then, filter is inserted into initial part of metal tube 4 (Fig. 1) so that by one side it touches surface of screen of electron-beam tube 1 (Fig. 1). Further, to electrostatic machine 2 (Fig. 1) diluted electrodes insulated high-voltage wires 6 (Fig. 1) with terminals on ends. One terminals are fixed on the balls of the electrodes of the electrostatic machine, and the other terminals are connected on both sides to ceramic filter 5 (Fig. 1) impregnated with heteropolyacid 1–12 of row having formula H₆[PW₁₀V₂O₄₀], after which using the power supply unit includes electron-beam tube 1 (Fig. 1) and waiting for 7 to 15 minutes to ensure stable operation of the electron-beam tube. After stabilization of operation of electron-beam tube smoothly rotate handle of electrostatic machine till appearance of greenish illumination 7 (Fig. 1) at opposite end of metal tube 2 (Fig. 1) and as shown in Fig. 2. With further increase in revolutions of rotating disks of the electrostatic machine, the luminescence becomes more intense owing to ionization of air owing to the directed flow of electrons which occur when the filter is exposed to heteropolyacid and has high-density charges which are formed on the surface of the electron-beam tube and when the ceramic filter is exposed to an electrostatic field. This action leads to reduction of heteropolycomplex, during which excess of charged particles appears on ceramic filter and free electrons are formed, "ejected" from the metal tube on the opposite side from the electron-beam tube, during which a directed ionizing channel in the air is formed.

EFFECT: high stability of the ionizing channel and reduced dependence thereof on weather conditions.

1 cl, 2 dwg

Description

The invention relates to methods for creating a directional ionizing channel in air and can be used for scientific research in the field of electricity, in particular, to obtain a gas-discharge plasma in air and to study its properties.

Known patent for "The method of obtaining ball lightning" [1].

In this invention, a special electrostatic field concentrator was used to create a ball lightning in a cathode ray tube, and a cathode ray tube was taken, giving a beam of electrons with an energy of about 3-5 keV. Before the start of the experiment, the cathode ray tube was heated for the stability of the radiation. After all the parameters stabilized, a high density electrostatic field was created through the glass screen of the cathode ray tube, that is, inside it, using a hub for 2-3 seconds, the field density should be sufficient to pass through the phosphor layer that covered the screen tubes, after which a black ball lightning was formed in the glass flask of the cathode ray tube, which could exist for 10–20 minutes autonomously without energizing it from outside. To check the last statement, the cathode-ray tube was turned off completely, and after switching on, a black spot appeared on the screen, smoothly enveloping the electron beam, which indicated the presence of a negatively charged ball lightning.

A long time for existence and black color for ball lightning is explained by the rarefaction of the atmosphere inside the bulb 10 ^-6 atm. Because of this, the energy loss due to ionization of atoms that are not participating in the process is rather small.

The known method of wireless transmission of electricity [2].

The invention relates to methods for wireless transmission of electrical energy and can be used as a means of transmitting electric charges without wires.

The method consists in obtaining a continuous stream of ball lightning, having a directed flight in the air space, behind which conductive channels are formed, charge carriers in which are hydrated ions of elements contained in the atmosphere.

The use of a continuous stream of charged particles forming a plasma column in the air, which is a chain of ball lightning, allows electrical energy to be transmitted without wires, because due to strong ionization of air and in the presence of hydrated ions, such a medium is a conductor that can directly affect electrical circuits and contacts.

Ball lightning, which are formed as a result of continuous exposure to a stream of an aqueous solution of heteropoly acids by a direct current, pushing off from an insulator, form a directed flow of charged particles, charge carriers in which are hydrated ions of elements in the atmosphere, namely, various structures of hydrated hydrogen atoms (for example, chain structures H ₅ O ₂ , H ₇ O ₃ , H ₉ O ₄ ). It should also be noted that the establishment of a stream of charged particles contributes to the force of electrostatic attraction between ball lightning, continuously flowing from the device.

This method has significant limitations. Since the above chain structures are very unstable and have a very short lifetime and, given the changing climatic conditions (fog, rain, wind, snow and others), the transmission distance of electricity is very dependent on the above factors, which as a result leads to significant losses of transmitted electric energy and requires the use of high-power energy sources, which entails an increase in weight and size characteristics and large power consumption.

Also, due to the variable climatic conditions, two parallel streams of ball lightning can overlap each other, causing air short circuits, which can be accompanied by an explosion and cause a power failure of an object.

Due to the low speed of departure of ball lightning, which, according to the description, is 0.006 km / s, the process stability can be disturbed.

This invention cannot be used to extract electricity from the environment.

The technical challenge is to develop a method that would allow to obtain in the air medium a directional ionizing channel of the required length, which could be oriented both in the horizontal and in the vertical direction, and that the ionizing channel obtained in this way would not depend on weather conditions it is stable in time, and the devices where this method is carried out would have small weight and size characteristics, which would be optimal for studying their properties.

The essence of the claimed technical solution lies in the fact that as a device for receiving a directional ionizing channel in the air environment uses a cathode ray tube 1 (Fig. 1) and the source of the electrostatic field, which can be used electrophore machine 2 (Fig. 1) .

The way to create a directional ionizing channel in air is as follows. To the cathode-ray tube 1 (Fig. 1) connect the power supply 3 (Fig. 1), which ensures the operation of the cathode ray tube. On the opposite side of the power supply unit to the screen of the cathode ray tube is connected a metal tube 4 (Fig. 1), which can be made of stainless steel, nickel, aluminum or copper, and inside which is a porous material, which, in turn, can be made of ceramic filter 5 (Fig. 1), and before placing the ceramic filter in a metal tube, the filter is impregnated with an aqueous solution of a hetero-polyacid 1-12 in a row, having the chemical formula H ₆ [PW ₁₀ V ₂ O ₄₀ ], with concentration from 45 to 75%. Then the filter is dried from 4 to 7 hours in a drying cabinet in the temperature range from 30 to 50 ° C. Next, the filter is inserted into the initial part of the metal tube 4 (Fig. 1) so that on one side it touches the screen surface of the cathode ray tube 1 (Fig. 1).

Next to the divorced electrodes of the electrophore machine 2 (Fig. 1) connect the insulated high-voltage wires 6 (Fig. 1) with terminals at the ends. Some terminals are mounted on balls of electrodes of an electrophore machine, while others are connected from two sides to a ceramic filter 5 (Fig. 1) impregnated with row heterogeneous acid 1-12 having the formula H ₆ [PW ₁₀ V ₂ O ₄₀ ], then using a block power supplies include a cathode ray tube 5 (Fig. 1) and wait from 7 to 15 minutes in order for the cathode ray tube operation to become stable. After stabilization of the cathode-ray tube operation, the handle of the electrophore machine begins to rotate smoothly until a greenish glow 7 (Fig. 1) appears at the opposite end of the metal tube 2 (Fig. 1) and as shown in Fig. 1. 2. With a further increase in revolutions of the rotating disks of an electrophore machine, the luminescence becomes more intense due to the ionization of air due to the directional flow of electrons arising from the effect on the filter impregnated with the heteropoly acid, high-density charges, which are formed on the surface of the ceramic filter by electrostatic field. This action leads to the restoration of the heteropoly complex, in the course of which an excess of charged particles appears on the ceramic filter and free electrons are formed, “ejected” from the metal tube on the opposite side from the cathode ray tube, in the course of which a directional ionizing channel is formed in the air.

Example 1. A method of obtaining a directional ionizing channel in air.

A device consisting of a cathode ray tube 1 (Fig. 1) was assembled, the operation of which was provided by the power supply unit 3 (Fig. 1), on the opposite side of which a metal tube was made, made of stainless steel, inside which was placed a porous material made from a ceramic filter 5 (Fig. 1) and impregnated with an aqueous solution of a heteropoly acid 1-12 of a series, having the chemical formula H ₆ [PW ₁₀ V ₂ O ₄₀ ] and with a concentration of 55%. Before the filter was placed in a metal tube, it was dried for 5 hours in an oven at 45 ° C. The filter was inserted into the initial part of the metal tube so that with one side it touched the screen of the cathode ray tube. Next, to the divorced electrodes of the electrophore machine 2 (Fig. 1), insulated high-voltage wires 6 (Fig. 1) were connected with terminals at the ends. Some terminals were attached to the balls of electrodes of an electrophore machine, while the others were connected from two sides to a ceramic filter 5 (Fig. 1) impregnated with a 1-12 heteropoly acid of the row, having the formula H ₆ [PW ₁₀ V ₂ O ₄₀ ], then using a block the power supplies switched on the cathode-ray tube 5 and waited for 10 minutes so that the work of the cathode ray tube became stable. After stabilization of the cathode-ray tube operation, the handle of the electrophore machine began to rotate smoothly until a greenish glow 7 (Fig. 1) appeared on the opposite end of the metal tube 2 (Fig. 1) and as shown in Fig. 1. 2. With a further increase in speed of the rotating disks of the electrophore machine, the glow became more intense.

Conclusion. This experiment, given in the example, confirms the technical essence of the claimed invention and the possibility of its use. Greenish luminescence in air is a consequence of the ionization of air due to the directed flow of charged particles that occur when exposed to a filter impregnated with a heteropolyacid, high density charges that form on the surface of a working cathode ray tube and when exposed to a ceramic filter with an electrostatic field. This action leads to the restoration of the heteropoly complex, as a result of which an excess of charged particles, in particular electrons, and “ejected” from the metal tube on the opposite side of the cathode ray tube, form a conducting channel in the air on the ceramic filter

Information sources:

1. RF patent №2168289 C1

2. RF patent №2223617 С2

Claims (2)

1. A method of creating a directional ionizing channel in air, including using a heteropoly acid as a chemical reagent, as well as a cathode ray tube generating electron beams, and creating a high-density electrostatic field, characterized in that to obtain a directional ionizing channel in air, cathode ray tube and a source of electrostatic field, which is used as an electrophore machine, where a blast is connected to a cathode ray tube A power tube is connected to the power supply that ensures the operation of the cathode-ray tube, and on the opposite side of the power supply unit to the screen of the cathode ray tube, inside which have a porous material made of a ceramic filter, and before placing the ceramic filter in a metal tube, the filter is impregnated with an aqueous solution of heteropoly acid number 1-12, having the chemical formula H ₆ [PW ₁₀ V ₂ O _40], at a concentration of 45 to 75%, after which the filter was dried from 4 to 7 hours in a drying cabinet in the range t The temperature is from 30 to 50 ° C and then the filter is inserted into the initial part of the metal tube in such a way that it touches the screen surface of the cathode ray tube with one side, then insulated high-voltage wires with terminals at the ends, where some terminals they are mounted on balls of electrodes of an electrophore machine, and the others are connected from two sides to a ceramic filter impregnated with a hetero-polyacid 1-12 row having the formula H ₆ [PW ₁₀ V ₂ O ₄₀ ], then using a pit these include a cathode ray tube and wait from 7 to 15 minutes so that the cathode ray tube becomes stable, and after stabilization of the cathode ray tube, the handle of the electrophore machine begins to rotate smoothly until a greenish glow appears at the opposite end of the metal tube and a further increase in the speed of the rotating disks of an electrophore machine, the luminescence becomes more intense due to the ionization of air due to the directional flow of electrons that occur when exposed Ilter impregnated with a heteropoly acid, high density charges that form on the surface of a cathode ray tube when an electrostatic field is applied to a ceramic filter. 2. The method according to p. 1, characterized in that the metal tube is made of stainless steel, nickel, aluminum or copper.

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