RU2414117C1 - Apparatus for electrophysical influence on atmosphere - Google Patents

Abstract

FIELD: physics. ^ SUBSTANCE: invention relates to technology for influencing the atmosphere. The apparatus has an earthed electroconductive grid, placed with clearance from corona conductors suspended along the surface of the earth. The electroconductive grid is placed on a surface which is equidistant from the surface formed by suspension lines of the corona conductors. ^ EFFECT: invention enables creation of conditions in the atmosphere, where mist is scattered and the cloud base is raised, as well as generation of a stable ion wind on the entire surface of the apparatus. ^ 2 cl, 1 dwg

Description

The invention relates to the field of technology intended for exposure to the atmosphere. Using the proposed device, it is possible to form in the atmosphere such conditions under which there will be dispersal of the fog and the rise of the lower border of cloudiness. The device can be used at airfields, highways, seaports, etc., where to control vehicles it is necessary to comply with the requirement for visibility range. In addition, the proposed device can be used to provide various sports and entertainment events in open areas.

Known methods for dispersing fogs based on artificial condensation of water vapor by using special substances (reagents). Reagents are delivered and spread in fog or cloudiness from aircraft (see, for example, US patent No. 2815928, IPC A01G 15/00, published December 10, 1957) using missiles (see, for example, USSR copyright certificate No. 576839, IPC A01G 15/00), shells (see, for example, Russian Federation Patent No. 2034444, IPC 6 A01G 15/00, published May 10, 1995).

As reagents, a mixture of chlorine carbon (patent No. 2160900, published on 06.06.1939), silver iodide (patent No. 2527230, published on 10.24.1950), an aqueous solution of calcium chloride with a thickener (patent No. 2934275, published on 26.04. 1960) and others.

Despite the accumulated experience in the practical use of reagents, the use of technology is limited only in relation to supercooled mists. Warm fogs are more stable and cannot be dispersed with the help of reagents.

Known methods based on electrophysical effects on the atmosphere (see, for example, USSR author's certificate No. 71260, IPC A01G 15/00, published July 31, 1948, US patent No. 3456880, IPC A01G 15/00, published July 22, 1969 USSR copyright certificate No. 29675, IPC A01G 15/00, published in 1948, application from Germany No. 4005304, IPC E01H 13/00). Known methods are based on the generation of electrically charged particles into the atmosphere. Devices that implement the known method use either raising the corona wires to the height of the cloud, which determines the high cost of resources and is not always feasible due to weather conditions, or blowing them with an air stream formed by technical means, corona electrodes installed at the surface of the earth.

A known method of dispersing fogs and clouds, which consists in generating electric charges into the atmosphere by connecting corona wires to the high voltage source, fixed through insulators on supports at the surface of the earth (see "Journal of Geophysical Research", Cambridge, Massachusetts, March 1962, t .67, pp. 1073-1082). Information about this method is also reflected in the domestic technical literature (see L. G. Kachurin, “Physical Foundations of Impact on Atmospheric Formations,” Gidrometeoizdat, Leningrad, 1978, pp. 287-293).

As follows from the above sources of information, the determining factor in the dispersion of fog in the known method is the space charge acting on atmospheric formations.

The closest technical solution to the proposed is a device according to the patent of the Russian Federation No. 2101922 C1, class. Е01Н 13/00, 01.20.1998, containing a grounded electrically conductive grid installed with a gap relative to the corona wires suspended along the surface of the earth.

This technical solution successfully enough solves the problem of exposure to the aerosol cloud. The aerosol cloud exposure process includes three main processes. The first is the initiation of condensation processes on finely dispersed aerosols, which in their natural size and lyophilicity could not be condensation centers. The second is the heating of the atmospheric space between the corona electrodes and the ground. The third is the ionic wind, the direction of which is from the corona electrodes to the ground. The efficiency of all these processes is determined by the stability of the corona discharge combustion and the value of the corona discharge current. However, stable formation of a corona discharge, which ensures ionic wind flows, contributing to a stable effect on the atmosphere, experimental studies have shown, can be achieved in a narrow range of variation of the gap between the corona electrodes and the grounded sect. With an increase in the gap at a given voltage, the ion wind velocity drops sharply and is almost imperceptible, with a decrease in the gap, breakdowns and system shutdown occur. Corona wires and a grounded mesh in a known device are installed along the surface of the earth and under the influence of weight sag and bend between the attachment points. The sag of the corona wires and the deflection of the electrically conductive grid in the known device is not controlled by anything, and their spread leads to a significant spread of the gap between the corona wires and the electrically conductive grid. The effective effect of a corona discharge is observed only in a narrow range of variation of the gap of the corona space. Ensuring a guaranteed clearance in a known design over the entire area of the corona space is difficult. And in places where the gap is less, breakdown occurs. Therefore, the maximum possible voltage of the installation is determined by the minimum gap between the corona electrodes and the electrically conductive grid. Given that the corona discharge current is proportional to almost the square of the voltage (see, for example, N.A. Kaptsov. Electronics. State Publishing House of Technical and Technical Literature. Moscow. 1956), deviations of the gap of the discharge gap from the calculated value significantly reduce the efficiency of electrophysical effects .

The aim of the proposed invention is to increase the effectiveness of exposure to fog.

To achieve the stated goal in a known device for electrophysical effects on the atmosphere, containing a grounded electrically conductive grid installed with a gap relative to the corona wires suspended along the earth's surface, the electrically conductive grid is installed on a surface that is equidistant to the surface formed by the suspension lines of the corona wires;

the electrically conductive grid is installed on a cylindrical surface, the guide of which is a chain line, the fixed ends of which are normal to the earth's surface passing through the suspension points of the corona wires.

The essence of the proposed method is as follows. Corona wires suspended along the surface of the earth form a certain surface, determined mainly by the sag of the wires under the influence of their weight. By measuring the parameters of the slack of the wires (or by calculation), the parameters of the surface formed by the corona wires are established. According to the obtained parameters of the lines of the corona wires, at equal distance from them along the normal to the earth's surface, corresponding to the selected gap of the discharge gap, frame beams are installed for the installation of an electrically conductive grid. Thus, the surface of the electrically conductive grid mounted on the frame, all the beams of which are at the same distance from the corona wires, it almost turns out to be an equidistant surface formed by the lines of corona wires. That is, the accuracy of the gap between the electrically conductive grid and the corona wires is ensured by the accuracy of the installation of the frame beams and their frequency and can be performed at the level specified at the design stage.

Given that the line of corona wires suspended along the surface of the earth is described by a chain line

(see, for example, http://www.exponenta.ru/educat/ciass/test/hyperb/index.asp) by installing an electrically conductive grid on a cylindrical surface, the guide of which is a chain line, the fixed ends of which are normal to the earth the surface passing through the suspension points of the corona wires, we get the surface of the grid, the equidistant surface of the corona wires, i.e. the gap between the corona wires and the conductive mesh will be the same over the entire surface.

The drawing shows a schematic diagram of the proposed device. The drawing shows a variant of the device when the conductive mesh is below the level of the corona wires. In the case when, according to weather conditions and the required nature of the impact, it is necessary to form an upward air flow, an electrically conductive grid can be installed above the corona wires. In this case, the suspension height of the corona wires should exceed the gap to the electrical conductive mesh by at least three times.

The device includes two rows of high-voltage insulators 1 mounted on supports 2. For each row of high-voltage insulators 1, power beams 3 are installed on their upper part. Corona wires 4 are fixed between the power beams 3. The fixing of the corona wires 4 can be different. For example, by fixing one end of the wire on the first beam with the fastening of the load of tension 5 on the other end of the wire with the corresponding reserve of wire on the fixed blocks 6, 7, mounted rotatably around its axis on the second beam. The installation of block 7 is intended to take the tension load under high voltage away from the grounded support 2. With a gap δ relative to the corona wires 4, the beams of the frame 8 are installed for mounting the grounded electrical wire mesh 9. The installation of the electrical wire mesh 9 can be performed either on the frame 8, in advance mounted on poles 10, as shown in the figure, or on ropes 11 stretched between the two extreme rows of poles 10. The tension of the cable 11 can be carried out similarly to the tension of the corona wires 4 by fastening one edge of the cable to the power beam 12, mounted on one line of the posts 10 with the suspension of the load of tension 13 at the opposite end of the cable 11. The cable 11 is stored in a fixed unit 14 mounted on the power beam 12, mounted on the opposite line of the posts 10. For convenience the tension of the end of the cable 11 can be fixed in the anchor support 15 through the lanyard 16. The height of the posts 10 and, accordingly, the surface of the beams of the frame 8 is made equidistant to the suspension line of the corona wires 4. The equidistance of the surface of the beams of the frame 8 l suspension lines of the corona wires 4 are provided by setting a constant gap δ from the corona wires to the upper surface of the frame beams, or by adjusting the tension force of the cables 11, the mass of the tension load 13 and the position of the attachment point of the cargo 13 to the cables I.

The corona wires 4 are connected to a high voltage power supply (not shown). The grounding of the high-voltage power source is carried out on the ground loop (not shown) associated with the conductive grid 9.

The proposed device operates as follows.

When applying high voltage to the corona wires 4 between the corona wires 4 and the grounded grid 9, a powerful electric field is formed and a corona discharge is ignited. The voltage value of the high-voltage power source is selected based on the conditions of resistance of the high-voltage insulators and the geometric relationships between the corona electrode and the grounded surface, being guided by the well-known relationships for corona discharge (see, for example, N.A. Kaptsov. Electronics. State Publishing House of technical and technical literature. Moscow. 1956). As an analysis of literary sources shows (see, for example, Kuleshov P.S. “An experimental study of the interaction of corona discharge and water evaporation http://zhumal.ape.relarn.ru/articles/2005/227.pdf, I.A. Rogov et al. "Modeling the process of motion of a droplet of moist air condensate in an electric field" http://www.holodilshchik.ru/mdex_holodilshchik_best_article_issue_10_2005.htm) and the results carried out by the authors of the proposed invention, by generating a corona discharge, it is possible to form a wind flow from the corona electrode to the conductive mesh with a speed of the order of 1 m / nuts. When a wind flow occurs, air masses mix, resulting in fog dispersal. In addition, during the generation of a corona discharge in the atmosphere, complex microphysical processes occur that also contribute to the destruction of the fog. The main parameter determining the speed of the ionic wind is the electric field strength. As shown by the results of experiments, the effective generation of ionic wind can be realized in a narrow range of the value of the gap of the corona space. The installation of a grounded electrically conductive mesh 9 over a surface equidistant to the suspension lines of the corona wires 4 will ensure a guaranteed tension of the grid over its entire area with a guaranteed gap δ relative to the corona wires, the accuracy of which can be maintained within a predetermined range. Since the corona wires are suspended along the surface of the earth, no matter how much they are stretched, including with the help of weights, they will sag relative to the surface of the earth. The value of this sag is determined by the mass of the corona wires 4, the span between the fixed ends and the force of their tension (mass of the load of tension 5). However, the sag shape of the corona wires 4, taking into account their small radius (δ ~ 1.0 mm) and insignificant moment of resistance to bending, practically corresponds to the known line, the chain line. See, for example, Applied Mathematics. Handbook of Mathematical Formulas, http://www.pm298.ru/spec15.php. The parameters of the chain line, in particular, the value of its sag at each point, are described by the well-known equation of the chain line and can be predetermined at the design stage. The equidistant surface of the electrically conductive grid to the corona suspension lines is a cylindrical surface, the guides of which are a chain line, the fixed ends of which are normal to the earth's surface passing through the suspension line of the corona wires. Theoretically, the proposed design of the device allows you to provide any, in advance, the specified accuracy of the gap between the corona electrodes and the electrically conductive grid.

Thus, the proposed solution, thanks to new features in combination with the known ones, makes it possible to provide the required accuracy of the gap of the discharge gap and to ensure the formation of a stable ionic wind at the maximum supply voltage of the corona wires, which will increase the efficiency of the effect on the fog and achieve the goal of the invention.

Claims (2)

1. Device for electrophysical impact on the atmosphere, containing a grounded electrically conductive grid installed with a gap relative to the corona wires suspended along the earth's surface, characterized in that the electrically conductive grid is installed on a surface that is equidistant to the surface formed by the suspension lines of the corona wires. 2. The device for the electrophysical effect on the atmosphere according to claim 1, characterized in that the electrically conductive grid is installed on a cylindrical surface, the guide of which is a chain line, the fixed ends of which are normal to the earth's surface passing through the suspension points of the corona wires.

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