RU2272096C1 - Method for fog dispersion - Google Patents

Abstract

FIELD: equipment for dispersing fog in general, for instance on roads and on airfields.

SUBSTANCE: method involves generating corona discharge in area adjoining object to be protected and extending for not less than 3 m from the object, wherein the corona discharge is generated by unidirectional electrically charged particle flow. Summary current strength of particle flow having cross-area of not less than 100 m² is not less than 0.1mA. Charged particle direction relative the object depends on fog type.

EFFECT: possibility to form air flow, which increases efficiency of fog dispersion.

2 cl

Description

The invention relates to the field of technology intended to influence atmospheric formations, namely to disperse fog over various ground objects, which include aerodromes, high-speed roads, seaports, etc., where it is necessary to fulfill the range requirements for driving vehicles visibility, as well as outdoor venues for various sports and entertainment events.

The main task to be solved when exposed to atmospheric formations is to increase the meteorological visibility range, which allows to ensure trouble-free operation of vehicles during fogging, as well as creating more comfortable conditions for entertaining and sporting events in open areas.

Known methods for dispersing fogs and clouds, consisting in the use of special substances (reagents) for the artificial condensation of water vapor.

As reagents, for example, in the USA, IPC A 01 G 15/00 patented substances such as 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 04/26/1960) and others. For the delivery of reagents and their distribution in fog or cloud can be applied aircraft (see, for example, US patent No. 2815928, IPC A 01 G 15/00, published on December 10, 1957), missiles (see, for example, USSR copyright certificate No. 576839, IPC A 01 G 15/00), shell (See., For example, the Russian Federation patent №2034444, IPC 6 A 01 G 15/00, published 10.05.1995 g).

Despite the accumulated experience in the practical use of reagents (see, for example, Bibilashvili et al. "Guidelines for the organization and conduct of anti-hail works", Gidrometeoizdat, Leningrad, 1981), their constant use, to one degree or another, leads to environmental degradation environment and requires the consumption of significant material resources, due to the need for the production of reagents in large quantities, the manufacture and operation of means of delivery of reagents to atmospheric formations.

From the point of view of using environmentally friendly processes when exposed to atmospheric formations, the use of electricity is the most promising.

Known methods based on the delivery to atmospheric formations of corona wires connected to a high voltage source (see, for example, USSR author's certificate No. 71260, IPC A 01 G 15/00, published July 31, 1948, US patent No. 3456880, IPC A 01 G 15/00, published on July 22, 1969).

The main disadvantage of the described method and known devices is the need to raise the corona wires to the height of the formation, which determines the high cost of fuel and energy resources and is not always feasible by weather conditions.

A known method, which consists in blowing an air stream formed using technical means, corona electrodes installed at the surface of the earth.

Technical solutions that implement the known method are a method of causing rain (see USSR author's certificate No. 29675, IPC A 01 G 15/00, published in 1948), as well as a device for destroying fog (see Germany’s published application No. 4005304 , IPC E 01 H 13/00).

The described method promotes the spread of ionized air, i.e. electrically charged particles upward, thereby accelerating the process of precipitation from clouds or the deposition of fog.

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 the fog in the known method is the space charge acting on atmospheric formations.

The closest technical solution to the proposed one is the method according to RF patent No. 2175880, IPC 7 01 D 5/00, which consists in generating a corona discharge with an intensity of formed ions of at least 10 ⁵ 1 / cm ³ . Such a technical solution makes it possible to initiate fog dispersal processes due to microphysical processes occurring in an ionized atmosphere. At the same time, the experimental studies carried out by the authors of the present invention showed that the efficiency of the fog dispersion process can be significantly improved by using ion wind energy in addition to microphysical processes.

The aim of the present invention is to increase the efficiency of the fog dispersion process.

To achieve this goal in the known method of dispersing fog, which consists in generating a corona discharge, the generation is carried out in the area adjacent to the protected object at a distance of at least 3 meters, oriented in one direction by a stream of electrically charged particles, the total current strength of which is at least 0, 1 mA with a cross-sectional area of the flow of at least 100 m ² ; the process of generating a corona discharge is preceded by determining the area of fog distribution relative to the protected object and the type of fog, and depending on the type of fog, the direction of orientation of the flow of electrically charged particles is carried out:

- for radiation fog, the flow is oriented either to the ground or along the surface of the earth in a direction directed from the protected object;

- for advective, frontal, slope and evaporation fogs along the surface of the earth in the direction opposite to the direction of the leakage of fog from the windward side of the protected object of leakage of fog, or to the side directed from the protected object.

The essence of the proposed method is as follows. When the flow of electrically charged particles is oriented in one direction, the particles in the process of their movement collide with the molecules and aerosols of atmospheric air and transfer part of their energy to them. A so-called ionic wind is created, which also carries droplets of fog. Due to the fact that the droplets of fog have different sizes (the fog is mainly a polydisperse structure, see E. McCartney's “Optics of the Atmosphere” p.186-193), the speed it reports will also be different, the probability of droplets colliding during their movement increases , they merge and enlarge, which contributes to the development of processes that accelerate the dispersion of fog. The difference in the velocity of the droplets depending on their size is justified by the different dependence of the inertial and aerodynamic forces on the size of the droplets. As is known, inertial forces are proportional to the mass of particles (see, for example, B.M. Yavorsky, Yu.A. Seleznev, "Physics Reference Manual", 4th edition, M., "Science", Main Edition of Physics and Mathematics , 1998, p. 164)

where m is the mass of the particle;

and - acceleration of its movement.

Given that the mass of a particle is proportional to its volume, then

where r is the particle radius.

Aerodynamic forces force the droplets to move with the air stream.

The ratio of aerodynamic forces to inertial forces determines the "connectedness" of particles with a gas stream

whose value as r → 0 tends to infinity.

Thus, the smaller the particle, the stronger it is associated with the flow, and small droplets of fog move almost at the speed of the ion wind flow, catching up on the way larger droplets.

In addition, by orienting the direction of flow in accordance with the proposed recommendation, air flows are formed that prevent the dripping of mist into the protected area and the influx of drier air into the protected area from the space free of fog. For radiation fog, drier air is introduced by the ionic wind from the upper layers or from an adjacent area free of fog for advective, frontal, slope fog and evaporation fog from the leeward side of air space (from the opposite side from the source of fog formation). In addition, droplets of fog formed by the air currents initiated by the ionic wind are carried into the area of space with drier air, which contributes to their evaporation and dispersion of the fog.

Implementation of the proposed method can be carried out by known technical means. For example, with radiation fogs having a vertical power of the order of several meters (see Khrgian "Physics of the Atmosphere", published by Moscow State University, Moscow, 1986, 327, p. 214), installing corona electrodes above the ground with a gap, corresponding to the conditions for the occurrence of a corona discharge, a flow of electrically charged particles is formed towards the ground (see, for example, RF patent No. 2108026, published April 10, 98, bull. No. 10, RF patent No. 2124287, published January 10, 1999, bull. No. 1 ) The air mass located in the corona discharge volume is also drawn into the movement by the ionized stream, and air flows are formed in which drier air from the upper atmosphere displaces the moist fog air from the protected area. As shown by experimental studies, the fog dispersion process is largely determined by the magnitude of the corona discharge current and the cross-sectional area of the generated ionized stream. The fog dispersal process is hindered by diffusion processes that contribute to the closure of the formed transparency window. Based on the obtained experimental data, it was found that when a corona discharge is generated in airspace with a cross-sectional area of at least 100 m ² and a corona discharge intensity corresponding to a corona discharge current of at least 0.1 mA, a noticeable area free of fog is noted.

Similar data were obtained during the formation of flows along the surface of the earth, oriented along the surface of the earth in the direction opposite to the direction of the leakage of fog from the windward side of the protected object of leakage of fog. The constructive implementation of the process of forming a flow of electrically charged particles along the surface of the earth in a given direction can also be carried out by known methods (see, for example, RF patent No. 2124288, published January 10, 1999, bull. No. 1). The remoteness of the directional flow formation region from the protected object is mainly determined by the speed of the fog flowing onto the object and the electric field propagation region from the corona discharge source. A stable manifestation of the fog dispersal process was noted when the corona discharge generation region was removed at a distance of at least 3 meters. The specific values of the corona discharge current, the cross-sectional area of the flow, and the distance of removal of the corona discharge region are determined by specific meteorological and orographic conditions and requirements for protecting the object from electric fields.

The effectiveness of the additional use of ionic wind energy to disperse fog is determined by the fact that for fog dispersion it is necessary to bring a significant mass of air (of the order of several thousand cubic meters) with a relatively low speed of several meters per second. Mechanical means, various kinds of fans, a helicopter propeller, a jet of a jet engine, etc., realize their energy mainly in the air speed. The flow rate realized by mechanical means is several tens of meters per second, and significant energy costs are required to impart directional movement to the air mass in the region of the order of several thousand cubic meters. energy is proportional to the square of the flow velocity. At the same time, to realize such a flow with the help of an ionic wind, only significant dimensions of the corona discharge generation system are required, amounting to an area of several hundred square meters.

Thus, the proposed solution, in addition to the well-known mechanisms of fog dispersion based on microphysical processes in an ionized atmosphere, thanks to a new set of features, allows you to attract an additional mechanism based on the use of ion wind energy, which will increase the fog dispersion efficiency and achieve the goal of the present invention .

Claims (2)

1. The method of dispersing fog, which consists in generating a corona discharge, characterized in that the generation is carried out in the area adjacent to the protected object at a distance of at least 3 m, oriented in one direction by a stream of electrically charged particles, the total force of which is at least 0.1 mA with a cross-sectional area of the flow of not less than 100 m ² . 2. The fog dispersion method according to claim 1, characterized in that the corona discharge generation process is preceded by determining the fog distribution region relative to the protected object and the type of fog, and depending on the type of fog, the direction of orientation of the flow of electrically charged particles is carried out: for radiation fog, the flow is oriented either towards the ground or along the surface of the earth in a direction directed from the protected object; for advective, frontal, slope fog and fog of evaporation along the surface of the earth in the direction opposite to the direction of leakage of fog from the windward side of the protected object of leakage of fog, or in the direction directed from the protected object.