RU2560236C1 - Fog dispersal device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device is intended for fog dispersal at a controlled territory whereat the visibility distance should be provided, and namely at aerodromes, expressways, sea ports, open sites for events, etc., and it may be used for the generation of air flows with large values of the cross section in the generated flow at arranged ventilation at a large airspace, at quarries, at installations intended for gas flow treatment from aerosol particles. The device comprises a grounded electroconductive network (3). The network is installed at a frame. Corona electrodes (5) are installed along the surface of the network. The electrodes are connected to a high-voltage source (6). The frame is made of an insulating material as a honeycomb panel. Ends of ribs (2) in honeycomb cells (1) of the frame coincide and are connected to contours of cells in the electroconductive network.

EFFECT: increasing operating efficiency of the device.

3 cl, 1 dwg

Description

The invention relates to the field of technology intended for dispersing fog in a controlled area, where it is required to ensure a guaranteed value of the visibility range in fog conditions, for example, airfields, express roads, seaports, open areas for various sports and entertainment events, etc. The proposed technical solution can also be used to form air streams with a large cross-sectional value of the formed jet (ventilation of air space over a large territory, such as quarries), as well as in devices for cleaning gas streams from aerosol particles.

Known methods of thermal dispersion of the fog. During World War II in England, a thermal method called FIDO was successfully used to disperse fog over airfields. See, for example, http://www.youtube.com/watch?v=gAIjxaJ2_Ag. Heat was generated during the burning of oil or fuel oil in burners installed on long pipelines along the runway. The ascending heat fluxes from the burnt fuel ensured the dispersion of fog over the airfield. This method has not found wide application due to the high cost of operation. It took several hundred thousand liters of fuel to disperse the fog per hour. Known methods of thermal dispersion of the fog, which in addition to thermal effects on the fog, use the kinetic energy of the heat stream. See, for example, US patent No. 2969920, published January 31, 1961, US patent No. 3712542, published March 15, 1971. This method also did not find its application due to the very high energy intensity of the method.

Known methods of electrical exposure to fog. So, in US patent No. 4671805, published June 9, 1987, describes a method of dispersing fog using an ion cloud. NASA's 3481 report from 1981 (see http://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/19820008785_1982008785.pdf,) presents research on the creation of ion generators. However, the practical application of ion generators for dispersing fog is not presented in published sources.

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,” L .: Gidrometeoizdat, 1978, pp. 287-293). Work on the test of this method, conducted with the participation of the authors, showed that the dispersion of fog by this method has a statistically significant result. See V.B. Lapshin, A.A. Paley. The results of field experiments to assess the effect of corona discharge on fog density. Meteorology and Hydrology, 2006, No. 1, pp. 41-47.

The closest technical solution to the proposed one is the device according to the patent of the Russian Federation No. 2124288 C1, class E01H 13/00, 12/19/1997, published on 1/10/1999, bull. No. 1. The known device comprises wires connected to a current source with a small radius of curvature of the surface, mounted on the insulators of the supports parallel to the conductive grid mounted in a vertical plane passing through the axis of symmetry of the adjacent supports.

Known technical solution successfully enough solves the problem of dispersion of the fog. See, for example, https://www.youtube.com/watch?v=3HnMTvwBOXk, https://www.youtube.com/watch?v=PGGkdaVStXs. The corona discharge generated by the corona wires creates an ionic wind, which is directed from the corona wires to a grounded grid. A cloud of fog passing through the corona discharge region receives an electric charge and is directed by an ionic wind, as well as by an external wind flow, to an earthed grid. Passing through the cells of the grounded grid, electrically charged drops of fog are separated from the wind stream, and the wind stream cleaned from fog is directed to the area of the space protected from fog. In addition, the ionic wind ensures the displacement of the fog from the controlled area and the replacement of moist misty air with drier air. For example, in the case of radiation fog, when moist moist air with fog accumulates below, and warmer dry air is above. The known device provides the release of colder moist air up and replacing it with drier air from above. At the same time, the stability of corona discharge burning, and, consequently, the efficiency of the device, largely depends on the accuracy of the gap between the corona wires and the grounded grid. In places where the gap is less than the design value, an electrical breakdown occurs, and the entire corona generation system turns off. In places where the gap value is greater than the design value, the intensity of the corona discharge is insufficient for efficient fog dispersion. To provide the required value of the accuracy of the gap in the known device is a very difficult technical task, since the corona electrodes and the grounded mesh are installed on various base surfaces. In addition, the use as corona electrodes of wires of small radius of curvature of the surface in the known device is also not effective. The wires during the corona discharge oscillate, which also leads to a change in the gap in the discharge space, to electrical breakdowns and instability of the corona discharge. The use of corona electrodes of known designs widely used in electrostatic precipitators significantly improves the efficiency of the device. In the designs of corona electrodes, fixed discharge points (needle electrodes) are widely used to increase the efficiency of corona discharge. See, for example, G.M.A. Aliev, A.E. Goic. Electrical equipment and power modes of electrostatic precipitators. Energy 1071. Page 43. To ensure in the known device the uniformity of the gap between all the needles of all the corona electrodes and the surface of the electrically conductive grid is practically impossible, which reduces the combustion efficiency of the corona discharge and reduces the efficiency of the entire device. It is difficult to ensure the flatness of the surface of the grid and to exclude the possibility of individual needles of the corona electrodes getting into the grid cells. The needles that fall into the space of the mesh cell practically fall out of the corona discharge generation process, since the distance to the grounded surface of such needles exceeds the calculated value. In addition to technical difficulties in ensuring the accuracy of the gap of the discharge gap, the known device revealed operational difficulties. During the generation of a corona discharge upwards, separable moisture accumulates on an earthed grid, which breaks down in drops and falls into the discharge gap. A spark breakdown of the discharge gap is initiated, and the conditions for the stable combustion of the corona discharge are violated.

The aim of the invention is to increase the efficiency of the device.

To achieve the stated goal, in a known device for dispersing fog containing a grounded electrically conductive grid mounted on the frame, along the surface of which are mounted corona electrodes connected to a high-voltage power source, the frame is made of an insulating material and made in the form of a honeycomb panel, the ends of the edges of the cell cells of which coincide and connected to the contours of cells of a grounded electrically conductive grid;

the corona electrode is made with a fixed discharge point mounted along the axis of the cell;

the contours of the cells of the grounded electrically conductive mesh are made with the inlet inward of the honeycomb structure along the surface of its ribs with a boundary equidistant from the surface of the corona electrodes.

The claimed technical result is ensured by the following features, which are endowed with the proposed solution with a new set of distinctive features. In the proposed technical solution, each electrode and a grounded surface are installed on the same structural base, made in the form of a cell edge, which allows achieving arbitrarily high values of the accuracy of the gap of the discharge gap. The mutual influence of the corona electrodes on each other is reduced, since each electrode forms a corona discharge only on its grounded surface and the charges generated by it are limited in the space of its cell, which makes it possible to increase the corona discharge power, increase the value of the discharge current and, therefore, the ion wind speed. The implementation of the contour of the grounded electrically conductive grid with the inlet inward of the honeycomb structure with a boundary equidistant from the surface of the corona electrode provides increased stability of the corona discharge (all points of the grounded surface are equidistant from the point with an increased gradient of the electric field on the surface of the corona electrode). In addition, the path of movement of electrically charged droplets along a grounded surface increases, and the efficiency of droplet collection increases. The collected moisture does not break down in the form of droplets from a grounded surface into the discharge gap, but is retained by wetting forces on the surface of the cell edge of the cell and rolls down along it and is removed from the discharge gap, which reduces the likelihood of spark breakdowns.

In fig. 1 presents a schematic diagram of the proposed device.

The device includes a honeycomb panel formed by interconnected honeycomb cells 1 formed from ribs 2 made of an insulating material. On one side, the ends of the ribs 2 of the cells 1 are coated with an electrically conductive material and grounded, thereby forming an electrically conductive grounded network 3. Thus, in the proposed design, the end surface of the honeycomb panel coated with an electrically conductive material plays the role of an electrically conductive network. Inside each cell along the axis of symmetry on the brackets 4, at a distance h from the end face 3 coated with an electrically conductive material, corona electrodes 5 are fixed, connected to a high voltage source 6. In Fig. 1, cell 1 is depicted with a square cross section. The cross section of the cell is selected at the design stage, based on technological capabilities, and may be different from that shown in Fig. 1 shape, for example, hexagonal or round. A round cell has a more uniform distance from the needle of the corona electrode to a grounded surface, but the degree of filling the panel space with corona elements is less. In square and hexagonal cells, the panel space is completely filled with corona elements. However, to ensure uniform corona discharge over the entire area of the grounded end surface, it is necessary to carry out work to optimize the shape of the corona electrode, which may already be not in the form of a needle, but in the form of a sharp blade (not shown in Fig. 1), the shape of which is determined based on modeling electric field between the corona electrode and the grounded end surface. The uniformity of the corona discharge can also be ensured by applying electrically conductive material not only along the ends of the edges of the cell cells, but also by capturing a part of the inner surfaces of the ribs 7 adjacent to the corona electrode to a line equidistant from the tip of the crown of corona electrode 8 (R = h). Thus, equality of the gap between the tip of the needle of the corona electrode and the nearby grounded surface will be ensured, which will ensure the stability of the combustion of the corona discharge. For mounting the device on the ground, the device can be equipped with appropriate fastening elements, which can be made on the basis of known technical solutions (not shown in Fig. 1). The fastening elements must provide reliable electrical isolation of the high-voltage voltage supplied to the corona electrodes from grounded structural elements.

The proposed device operates as follows.

When a high voltage is applied to the corona electrodes 5 between the corona electrodes 5 and the grounded surface formed by an electrically conductive material deposited on the ends of the ribs of the cells 3 and part of the inner surfaces of the ribs 2 to a line equidistant from the tip of the crown of the corona electrode 7, a powerful electric field is formed and ignited corona discharge. The value of the voltage of the high-voltage power source is selected based on the stability conditions of the insulating material of the ribs of the cell 2 and the geometric relationships between the corona electrode and the grounded surface, guided by the known relationships for corona discharge (see, for example, N.A. Kaptsov. Electronics. M .: State publishing house of technical literature, 1956).

When a corona discharge is generated, an ionic wind is generated from the corona electrode to the grounded electrode. The speed of the ionic wind is about 1 m / s. (See, for example, Kuleshov PS “Experimental study of the interaction of corona discharge and water evaporation http://zhurnal.ape.relarn.ru/articles/2005/227.pdf. IA Rogov and others.“ Modeling the process of the movement of a droplet of condensed moist air in an electric field ” coated with conductive material. Formed by the ionic wind, an air stream containing droplets of mist enters the discharge gap formed in each cell 1, where the droplets of mist acquire an electric charge. When the air flow in the cell 1 passes by the grounded conductive coatings 3 and 7, electrically charged droplets are deposited by the electric field on their grounded surfaces and are separated from the wind flow. Since the contours of the cells of the grounded electrically conductive mesh 7 are made with an inlet inside the honeycomb structure, the path of movement of electrically charged drops along the grounded surface is extended, which increases the efficiency of the deposition of drops. The air stream cleared of droplets leaves the cell outside, by inertia moves to the protected area and displaces fog from it. Drops of fog collect on the surfaces of grounded electrically conductive coatings 3 and 7 and, under the influence of their own weight, flow down either along the end surface 3 of the honeycomb panel (when the cell axis is horizontal to the ground) or along the surfaces of the ribs 2 (when the cells are inclined). If necessary, special means may be provided for the design of the device to collect the separated moisture. A corona discharge is formed between the tip of the needle of the corona electrode 5, fixed with a bracket 4 on the edge of the cell 2, and the grounded surface of the electrically conductive material deposited on the surface of the rib of the cell 2. Since both the tip of the needle of the corona electrode and the grounded surface are based on the same a structural element - the edge of the cell, the proposed technical solution allows to ensure maximum accuracy of their relative position, to achieve maximum corona discharge efficiency and achieve the objectives of the invention.

Claims (3)

1. A device for dispersing fog containing a grounded electrically conductive grid mounted on the frame, along the surface of which are mounted corona electrodes connected to a high-voltage power source, characterized in that the frame is made of an insulating material and made in the form of a honeycomb panel, the ends of the edges of the cell cells of which coincide and connected to the contours of cells of a grounded electrically conductive grid. 2. The device for dispersing fog according to claim 1, characterized in that the corona electrode is made with a fixed discharge point installed along the axis of the cell. 3. The device for dispersing fog according to claim 1, characterized in that the contours of the cells of the grounded electrically conductive mesh are made with the inlet inside the honeycomb structure along the surface of its ribs with a boundary equidistant from the surface of the corona electrodes.