RU2422584C1 - Method of fog dissipation - Google Patents

Abstract

FIELD: electricity. ^ SUBSTANCE: fog spread direction relative to a protected object is identified. A corona discharge is generated at a windward side relative to the protected object by a flow of charged particles aligned towards a side that is directed at the protected object. Generation of an aligned flow of charged particles is realised by a corona discharge between corona-forming electrodes and a collecting electrode, a significant portion of surface of which is transparent for air flow passage. A collecting electrode may be an electroconductive mesh, or a lattice, or vertical stands installed with a gap relative to each other. Transparency of the collecting electrode structure, i.e. the ratio of through holes area to the total area of the electrode must not make at least 50%. ^ EFFECT: increased meteorological distance of visibility and improved conditions of appropriate vehicles navigation.

Description

The invention relates to the field of technology designed to disperse fog in the area where objects are located, where it is necessary to meet the requirements for visibility (airfields, highways, seaports, etc., as well as open areas for various sports and entertainment events).

Known methods for dispersing mists based on the use of special substances (reagents) for the artificial condensation of water vapor.

According to US patent No. 2160900, published 06.06.1939, as the reagents used a mixture of chlorine carbon. US patent No. 2527230, published on 10.24.1950, it is proposed to use silver iodide as a reagent. An aqueous solution of calcium chloride with a thickener is claimed in US patent No. 2934275, which is published 04/26/1960. The delivery of reagents and their distribution in fog or clouds is proposed to be carried out using airplanes (see, for example, US patent No. 2815928, IPC A01G 15/00, published December 10, 1957), 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).

Despite the experience gained in the practical use of reagents (see, for example, Bibilashvili et al. Guidelines for the organization and conduct of anti-hail works. L .: Gidrometeoizdat, 1981), their constant use, to one degree or another, leads to environmental degradation 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.

Technical solutions protected by USSR author's certificate No. 71260, IPC A01G 15/00, published July 31, 1948, and US patent No. 3456880, IPC A01G 15/00, published July 22, 1969, suggest methods of electrical exposure to an aerosol cloud. Electrical exposure in the devices described above is carried out by delivering corona wires connected to a high voltage source to the aerosol cloud.

The complexity of the implementation of the described method and known devices is the need to raise the corona wires to the height of the cloud, which determines the high cost of fuel and energy resources and is not always feasible according to weather conditions.

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

In the description of the USSR author's certificate No. 29675, IPC A01G 15/00, published in 1948 (Method of causing rain.), As well as the application of Germany No. 4005304, IPC E01H 13/00, a device that implements the known method is presented.

The method provides for the distribution of ionized air, i.e. electrically charged particles upward, thereby accelerating the process of precipitation from clouds or the deposition of fog.

There is a method of dispersing fogs, 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 US Patent No. 6,152,378). This method promotes the propagation of electrically charged particles in the area designated for diffusion of fog. The electric charges generated by the corona electrodes provide charging of atmospheric aerosols and mist droplets. Due to the fact that electric charges localized on the surface of aerosols contribute to an increase in the initiation of condensation processes, the process of evolution of water aerosols is intensified. Evolution helps to reduce the concentration of particles and their enlargement, which leads to an increase in the range of visibility.

The closest technical solution to the proposed one is the method according to RF patent No. 2272096, IPC E01H 13/00, which consists in generating a corona discharge 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 force the current 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.

This technical solution successfully enough solves the problem of exposure to the aerosol cloud. However, to increase the effectiveness of the impact, especially when the fog flows onto the protected object at a high speed, it is necessary to increase the intensity of the generated ion wind flows, which requires an increase in voltage on the corona electrodes and, as a result, power sources with increased voltage, increased insulation requirements, which leads to more expensive construction.

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

To achieve the stated goal in the known method of dispersing fog, which consists in determining the direction of propagation of the fog relative to the protected object and the subsequent generation of the corona discharge by an oriented stream of electrically charged particles, the generation is carried out from the windward relative to the protected object stream of charged particles oriented towards the direction directed to the protected object .

The formation of an oriented flow of charged particles is realized by corona discharge between the corona electrodes and the precipitation electrode, a significant part of the surface of which is transparent for the passage of air flow. The essence of the proposed method is based on the effect of droplet separation revealed by the inventors. In the process of generating a corona discharge in a system of corona electrodes installed with a gap relative to the precipitation electrode, a significant part of the surface of which is transparent for the passage of air flow, the droplet dispersion is separated. To form a flow of electrically charged particles oriented in one direction in the precipitation electrode, through holes are made (the precipitation electrode can be made in the form of a grid, lattice, etc.) through which air perturbed by charged particles generated during the corona discharge (ionic wind) passes. When a wind stream formed by an ionic wind passes through a precipitation electrode, fog drops are separated on the surface of the precipitation electrode. If we omit the description of complex microphysical processes occurring in the discharge gap, the process of deposition of droplets on the surface of the precipitation electrode can be compared with the processes occurring in the electrostatic precipitator. When droplets pass through the discharge gap, droplets receive an electric charge. Electrically charged droplets in their movement together with the air flow to the holes in the precipitation electrode, due to electrical attraction, deviate from the trajectory of the air flow and fall on the surface of the precipitation electrode. Separated droplets are deposited on the surface of the precipitation electrode, after they are enlarged to the size where gravitational forces exceed the value of the wetting forces, they fall down, and the air purified from the droplets, carried away by the ionic wind, which coincides with the direction of the natural wind flow, is directed to the controlled area and displaces foggy cloud. As a result, the protected area is cleared of fog. The fog dissipates. As established in the course of experimental studies, when fog passes through a precipitation electrode with a transparency of 75% (wire mesh of a cell d = 3 mm with a cell of 20 × 20 mm), the attenuation of fog reached 85% over the entire area of the corona discharge generation system. The range of the stream stream cleared of fog is determined by the area of the corona discharge generation system and turbulent disturbance of the atmospheric boundary layer. In the experiments performed for the installation, the size of the generation system of which was 1.5 × 1.5 m, at a distance of 12 m, a stream of wind flow was recorded at a speed of 0.5 m. From aerodynamic conditions it is known that washing the stream stream over its entire cross-sectional area in an unperturbed atmosphere starts at a distance of at least 10 gauge jets. Thus, based on the theoretical calculations of the aerodynamics of the jet’s movement, it is possible to carry out scenario calculations of the propagation region of a fog-cleaned air stream in the protected area, to determine the areas in which the stream of air leaving the corona discharge system will displace the foggy cloud, provide fog light, and choose required dimensions of the corona discharge generation system.

If, in a known technical solution, the stream of air flow generated by the ionic wind from the corona discharge generation system was directed against the movement of the natural air stream that pushed the fog cloud onto the protected object, the energy of the ion wind flow was used to prevent the fog from moving into the protected area, and the air flow of the ionic wind was formed in the direction from the protected object. That in the proposed solution by using the mechanism of separation of droplets of fog, the air flow from the ionic wind is combined with the natural flow. Protection of the controlled area from fog is carried out not by blowing droplets of fog, as in the known solution, but by their separation on the precipitation electrode. As calculations and experiments show, fog dispersal by droplet separation, especially for advective, frontal, slope fog, is energetically more profitable and more efficient. When implementing the proposed solution, the generation of the corona discharge is carried out from the windward side of the protected object, which allows combining the energy of wind flows of natural wind and ionic wind. As a result, the propagation range of the enlightened jet is increased, which makes it possible to increase the efficiency of fog dispersion and achieve the objective of the invention.

Implementation of the proposed method can be carried out by known technical means. As a power source, a high voltage power source similar to the power source used in electrostatic precipitators can be used. Corona electrodes can be used by analogy with corona electrodes of electrostatic precipitators. As a precipitation electrode, an electrically conductive grid can be used, either a grating or vertical racks installed with a gap relative to each other. The transparency of the design of the precipitation electrode (the ratio of the area of the through holes to the total area of the electrode) should be at least 50%. The ratio of the combination of the area of the through holes to the area of the grounded surface is determined by the requirements for droplet separation and the aerodynamic resistance that the precipitation electrode exerts for the passage of air flow. The lower the transparency of the precipitation electrode, the more efficient the droplets of fog are separated, but at the same time, the greater the resistance to the air flow, the smaller the propagation range of the jet cleaned from fog. The choice of a specific ratio of the parameters of the precipitation electrode, and the entire corona discharge generation system, is carried out at the design stage taking into account the orographic conditions of the terrain, meteorological data, parameters of the area or volume of the protected object and other initial data, can be made on the basis of known theoretical dependencies using experimental modeling .

Thus, the proposed solution, thanks to a new feature in combination with the known ones, allows to increase the intensity of the generated ion fluxes, which will increase the efficiency of exposure to the aerosol cloud and achieve the goal of the invention.

Claims (1)

The method of dispersing fog, which consists in determining the direction of propagation of fog relative to the protected object and the subsequent generation of the corona discharge by an oriented stream of electrically charged particles, characterized in that the generation is carried out from the windward relative to the protected object stream of charged particles oriented in the direction directed to the protected object.