RU2039403C1 - Device for transportation and simultaneous purification of air - Google Patents

Abstract

FIELD: ventilation equipment. SUBSTANCE: device is meant for transportation and simultaneous purification of air with the aid of electric ion wind aura. It has body with corona-forming electrode and air path going from inlet hole and incorporating electrode-target placed at some distance from axis of inlet hole in symmetry relative to this axis. Body is manufactured with provision for deviation of trajectory of air flow downstream of inlet hole from rectilinear one. This ensures radial or angular displacement of air flow with formation of at least one air channel displaced relative to symmetry axis of body. EFFECT: increased operational efficiency. 19 cl, 14 dwg

Description

 The invention relates to electrical engineering.

 The closest known technical solutions to the invention is a device for transportation and simultaneous purification of air, containing a corona electrode and a target electrode, which are located at some distance from each other and each of which is connected to the corresponding terminal of a DC source, and the configuration of the corona electrode, as well as the potential difference and the distance between the corona electrode and the target electrode are such that they ensure that the corona electrode discharge, which causes the formation of air ions, which migrate to the target electrode and give them their electric charge under the influence of an electric field, moreover, during the movement of air ions towards the target electrode, ions collide with electrically neutral air molecules, thereby transmitting electrostatic forces and dragging them to the target electrode, which ensures the transportation of air in the form of an ionic (corona) wind.

 When air contains polluting aerosols, i.e. suspended solids and liquid droplets, these pollutants are electrically charged by air ions formed by a corona discharge, and, therefore, can be electrostatically deposited on the target, if the target has a suitable configuration, or in a capacitor separator located behind the target. Thus, it is possible to provide air purification by transporting air through the device using an electric ion (corona) wind.

 However, such a device must satisfy such requirements as large volumetric air flow through the device, high cleaning ability, small size, moderate potential difference between the corona electrode and the target, and at moderate levels of high voltage corona discharge, which should not be too high in connection so that as a result of a corona discharge, gases harmful to humans are formed, in particular ozone and nitrogen oxides. This is due to several not easily resolved and closely related problems.

 It is possible to provide both substantial air flow rates and significant air volumetric flow rates through a corona discharge current acceptable with respect to the formation of ozone and other harmful gases when the corona electrode and the target electrode are located at a considerable distance from each other and the corona electrode effectively shielded, as a result of which the product of the ion current and the distance of migration of ions in the upstream direction from the corona electrode are very small. However, increasing the distance between the corona electrode and the target requires increasing the potential difference between the corona electrode and the target in order to efficiently ignite the corona discharge. the consequence of this is an increase in high voltage levels at the corona electrode and / or target, which in turn leads to problems with insulation and spark overlap (breakdown). In addition, the need for preventing inadvertent contact of a person with electrodes under high voltage is increasing. It was found that when the corona electrode and the target electrode are axially spaced apart in a direct air duct (channel), which is the most natural device, the air flow has a noticeable tendency to concentrate in the central part of the air duct. This is true even when the target is located as close to the walls of the air duct as possible. Therefore, to meet the requirement of ensuring a large air volumetric flow rate, a large cross-section of the air duct is necessary and, therefore, the device must be large. In addition, when placing the target near the walls of the air duct, electrical insulation of the inner surfaces of the walls is necessary. It was found that during operation of the device, the electrically insulated surfaces of the walls receive an electrostatic charge, which adversely affects the corona discharge and the corona electrode, preventing proper ignition of the electrode. In addition, when placing targets near the walls of the air duct, in combination with the laminar flow of air in the channel, the path that electrically charged aerosol pollutants must travel when moving towards the target surfaces becomes relatively long and, therefore, becomes a relatively low degree of air purification. In principle, an improvement in this regard can be obtained by increasing the axial length of the target surfaces, or mainly by using either a large number of mutually parallel and less widely spaced target surfaces with intermediate surfaces having opposite polarity, or using a conventional capacitor separator behind the target in the air channel. All these solutions, however, require a significant increase in the overall dimensions of the device and, from the point of view of ensuring the most efficient cleaning, the last two solutions mentioned also lead to a significant increase in the resistance to air flow in the channel. This increase in flow resistance must, in turn, be compensated by increasing the corona discharge current and / or the distance between the corona electrode and the target electrode, and an increase in corona discharge current leads to an increase in the amount of ozone and other harmful gases generated, both of which also require greater potential difference between the electrodes. Thus, it was found that with such a design it is very difficult to obtain a satisfactory device for transporting air, which would simultaneously clean the transported air when transporting it using electric corona (ion) wind.

 The aim of the invention is to increase the efficiency of transportation and simultaneous purification of air.

 In Fig.1, an axial section of the first embodiment of the proposed device is shown; figure 2 section aa in figure 1; figure 3 axial section of a second variant of the proposed device; in Fig.4 a section bB in Fig.3; figure 5 axial section of a third variant of the proposed device; in Fig.6 section BB in Fig. 5; 7 is an axial section of the fourth variant of the proposed device; in FIG. 8 section GG in FIG. 7; Fig.9 embodiment of the separation wall located opposite the inlet made with the hole; figure 10 is a section of a fifth embodiment of the proposed device, which improves the first version of the device; figure 11 is a section of a sixth embodiment of the proposed device, improving the third option; on Fig section of the seventh variant of the proposed device, improving the third option; in FIG. 13 and 14 are views of the eighth and ninth variants of the proposed device, equipped with special means for removing harmful gases generated by corona discharge.

The proposed device (see Fig. 1 and 2) contains a housing 1 having an inlet 2 of rectangular cross section, in which a corona electrode K in the form of a thin wire located in the central plane passing through the hole 2, two flat and thin target electrodes are installed M, which are parallel to each other and to the central plane passing through the inlet 2 at a considerable distance from the plane and symmetrically relative to it from its opposite sides, resulting in an angle α under which the corona electrode K "looks" at two targets M, has a significant value. in the case of the device in accordance with the invention, this angle α can be at least 60 ^about and can even be much more than 60 ^about , and in some embodiments, the invention can reach almost 180 ^about . This provides a highly efficient and stable ignition of the corona discharge at the corona electrode K using a moderate potential difference between the corona electrode and the targets. The distance between the corona electrode and the targets, i.e. the path of movement of ions from the corona electrode to the targets is large (the length of the dashed lines in Fig. 1). The magnitude of the forces causing the flow of air depends on the length of the path traveled by the ions and the strength of the ion current.

 The housing 1 (see FIGS. 2 and 3) is provided with a partition or intermediate wall 5, which is shaped so that the air flow path behind the corona electrode K symmetrically branches outward on both sides of the central plane passing through the inlet 2 into As a result, two through channels 6 and 7, remote from each other, are formed, located at a considerable distance from the central plane passing through the inlet 2, and targets M are located in these two channels 6 and 7. This design does not Allows the air flow coming through inlet 2 to continue to move straight ahead near the central plane passing through inlet 2, forcing it to go towards targets M and pass them in the air channels 6 and 7. Despite the fact that this design deflects the air the flow and makes it change direction, thanks to this design provides a much more efficient and greater air flow. This is explained by the fact that the direction in which the air flows coincides to a very large extent with the direction of the forces driving the air flow generated by the ion flow passing from the corona electrode K to targets M. This fact, together with the fact that the angle α can be large as a result of which effective and stable ignition of a corona discharge can be achieved using a moderate potential difference when using at the same time a relatively large distance between the corona electrode and the targets, it is possible the ability to create a device that will transport air very efficiently using a moderate potential difference between the electrodes and the corona discharge current, which may be acceptable in relation to the formation of ozone.

 In addition, since the air flow is forced to move in close proximity to thin targets M on both sides, when these thin targets are located in the center of the through channels 6 and 7 (see Figs. 2 and 3), the sedimentation of suspended contaminants on the surface of the targets becomes more effective. The position of the targets M in the channels 6 and 7 can be changed in order to obtain the required air flow from both sides of the targets.

 It is advantageous when the DC voltage source 4, to which the corona electrode K and the target electrodes M are connected, has an earthed middle terminal, as a result of which the corona electrode and the targets receive opposite polarities with respect to the Earth and at the same time lower voltage levels with respect to the Earth. Since the targets M are located at a distance from the side walls of the housing 1 and the intermediate (separation) wall 5, these walls can be electrically conductive and grounded. This means that these walls are safe from the point of view of contact with them and cannot be charged electrostatically and, therefore, cannot have a harmful effect on the corona discharge at the corona electrode K. It is advisable to connect the corona electrode K and the target M to voltage source 4 through a very high resistance, limiting short circuit currents to safe values in the event of a short circuit of one of the electrodes.

Since the bulk of the ion current from the corona electrode K passes to the edges of thin targets M located closest to the corona electrode K, only these edges of the targets need to be made electrically conductive or semiconducting and connected to a voltage source. The remaining part of the thin targets M, which acts only as a surface for the deposition of electrically charged pollutants suspended in aerosol form, can have a very high resistivity, for example, it may contain antistatic material (or a material treated so that it becomes antistatic) having a specific resistance about 10 ¹⁰ -10 ¹³ Ohms. It is these last parts of the targets M that receive a very small current, the value of which corresponds only to the electric charge of pollutants deposited on the surfaces of the targets. This design of the targets M makes them completely safe from the point of contact with the air channels 6 and 7 through the inlet openings 6a and 7a of the targets. If necessary, the edges of the targets facing the corona electrode K can be rounded and made much thicker in order to ensure the mentioned edges are more efficient to receive and divert the ion current from the corona electrode without the danger of the appearance of a corona, the so-called reverse corona, at the targets. The configuration of these edges of the targets can also be adapted to the flow of air passing past these edges.

 Advantageously, a shielding electrode S is placed upstream of the corona electrode and connected to a potential equal to that of the corona electrode so as to prevent ion migration from the corona electrode in an undesired direction. When the corona electrode K has the form of an elongated thin wire (see FIGS. 2 and 3), the shield electrode S may, for example, have the shape of a rod of relatively large diameter running parallel to the corona electrode K.

 The inlet 2 is usually closed with a grid 8, which prevents unintentional contact with the shield electrode S and the corona electrode K. The grid 8 can be electrically conductive and can be grounded in the same way as the side walls and the intermediate wall 5 of the housing 1. When the grid 8 is located on such the distance from the corona electrode K, so that no ion current will pass from the corona electrode K to the grid 8, the shield electrode S can be eliminated and the grid will provide the required shield effect.

 The corona electrode K need not be axially located inside the inlet 2, as in the case shown in FIG. 2, and may be located in the plane of the inlet 2 or even axially outside the aforementioned hole. In such cases, the grid 8 gives the shape in which the grid surrounds the corona electrode K, thereby preventing inadvertent contact with the electrode.

 The device (see FIGS. 1 and 2) may also have a circular cross section, i.e. round inlet. In this case, the corona electrode will be a straight wire (needle-shaped) electrode located axially along the center line passing through the inlet 2. In addition, in the case of this latter embodiment, two separate air channels 6 and 7 will have the shape of a circular channel, which located coaxially and around the center line passing through the inlet 2, and in which is placed a cylindrical hollow target electrode.

 The device (see FIGS. 5 and 6) has an inlet 2 of circular cross section and a needle-shaped (in the form of a short straight wire) corona electrode K located axially along the center line passing through the hole 2. In this embodiment, the housing 1 and its dividing wall 5 such a shape is given that the air flow path behind the corona electrode K branches symmetrically outward from the center line passing through the inlet 2 to the circular air duct 6 diverging conically relative to the central Inlet line. In the channel 6, a thin-walled, truncated cone-shaped target electrode M is installed, which runs parallel to the channel walls and is located between the walls. Obviously, a device of this design will in principle act in the same way as the described device shown in FIGS. 2 and 3, and will give the same advantages as this device. It is possible that in the case of the device made in accordance with FIG. 3 and 4, the air flow mode is somewhat more favorable, since the air channel 6 diverges outward in the direction coinciding with the direction from the corona electrode K and the target M. On the other hand, the external dimensions of the device made in accordance with FIGS. 3 and 4 will be larger than the dimensions of the device made in accordance with FIGS. 1 and 2. Since the corona electrode K of the device shown in FIGS. 3 and 4 is a needle-shaped (in the form of a short straight wire) electrode passing along an axial line, then a suitable rmoy for screening electrode S will form rings located on the corona electrode K upstream.

 An embodiment incorporating the same principles as shown in FIGS. 3 and 4 can also be used in a device having a rectangular inlet and, therefore, two separate rectangular air channels (corresponding to channels 6 and 7 in FIGS. 1, 2 ) diverging symmetrically with respect to the central plane of the inlet. In this case, each of the two air channels will contain, as in the embodiment shown in FIGS. 2 and 3, a flat thin target electrode, and the corona electrode will be in the form of a wire and will be located similar to that shown in FIGS. 2 and 3.

 In the device shown in FIGS. 5 and 6, the housing 1 and the dividing wall 5, which in this case is made flat, have such a shape that the air flow path behind the corona electrode K branches at right angles into two oppositely directed air channels 6 and 7 extending perpendicular to the central plane of the inlet. It has been found that this option will transport and purify the air very efficiently. The angle α within which the corona electrode K "sees" the target M can be made very large in this case, and the corona electrode K can be placed in the plane of the housing wall or immediately outside of it, so that the inlet (pipe) 2 can be made very short.

 Figures 7 and 8 show a similar embodiment having a circular inlet 2 and, therefore, only one air channel 6, which extends radially in all directions perpendicular to the center line of the inlet and in which a flat ring target electrode M is placed.

 In the described devices in accordance with the invention, the target (s) is made (s) thin (them), i.e. small thickness with respect to the surface area, and is located (s) parallel to the bounding walls of the channels 6 and 7, in which she or they are placed (s), but the configuration and position of the targets may be different. Thus, targets can contain, in all cases, electrically conductive or semi-conductive surfaces located in close proximity to the inner surface of the channel walls or directly on this inner surface. The indicated surfaces of the targets can thus be grounded to eliminate all problems with insulation and breakdown, in which case the entire high voltage potential will be on the corona electrode. However, since, as was mentioned, when using the device in accordance with the invention, it is possible to operate with a relatively moderate potential difference between the corona electrode and the target, and despite this, with a significant distance between the corona electrode and the target, the fact that the corona electrode is underneath potential of high voltage relative to the Earth, does not have to lead to problems with reliable insulation or breakdown. Such targets located on or very close to the inner surface of the channel walls can also have a potential different from the Earth’s potential, similar to the described options, in which case the channel walls must be electrically isolated. In the case of a device in which the surfaces of the targets are superimposed on the inner surface of the walls of the channels or are located very close to it, parallel to the air channels in the middle, they can be similar to targets M in the embodiments shown in Figs. 2-9, thin electrically insulated electrode elements that, when electrostatically charged form together with targets near the channel walls condenser-separators for efficient deposition of aerosol pollutants in the air stream.

The device (see FIGS. 1, 2) has the same configuration as the device shown in FIG. 5 and 6, having a square or rectangular external profile and a rectangular inlet (nozzle) 2, which extends throughout the vertical extent of the device and from which the inflowing air is branched at an angle ^of 90 to two oppositely directed airflow channels 6 and 7. The corona electrode K is a wire and is located in the Central plane passing through the inlet 2, together with a shielding electrode S, as described above. In each of the channels 6 and 7, there is a target system consisting of three thin targets M, of which two form the outer side walls of the corresponding air channel, and the third runs parallel to the said outer side walls in the middle between them. All electrode elements M are grounded together with one terminal of the voltage source 4, and the corona electrode K, together with the shield electrode S, is connected to the other terminal of the voltage source. In this embodiment, the wall 5, which separates and deflects the air flow entering through the inlet 2, is preferably electrically isolated. The walls of the housing 1, forming the inlet 2, can be electrically insulated or electrically conductive and grounded with a grid 8 covering the inlet 2. The air flow enters through the opening 2 and exits through two oppositely directed channels 6 and 7, as described in the device, shown in FIGS. 5 and 6. In the middle between the targets M in the air channels 6 and 7, additional thin, electrically conductive or semi-conductive electrode elements 10 are installed. The latter are electrically isolated relative to the surrounding For example, objects are fixed in the insulated end walls of the housing, and during operation the devices will be charged electrostatically, receiving voltages of the same polarity as that of the corona electrode K relative to targets M. Together with the electrode elements M of the targets, the elements 10 form capacitor (capacitor) separators in principle traditional type, providing effective deposition of aerosol pollutants carried by the air flow on the elements of the M targets. The edges of the elements 10, located closest to the corona electrode K, can be provided with protruding petals that favor the required electrostatic charge on the electrode elements 10. The electrode elements M and the elements 10 in each of the air channels 6 and 7 can be made as one unit a single easily removable unit that can be easily removed for cleaning or replaced if the M elements of the targets are excessively contaminated with airborne contaminants.

A device made in accordance with FIG. 12 and having dimensions of 400x400 mm and the remaining dimensions shown in the drawing in mm, were tested in practice at a corona discharge voltage of 20 kV and a corona discharge current of approximately 8 μA. An air flow rate of approximately 60 m ³ / h was obtained, with more than 99% of the aerosol pollutants transported from it being recovered from the air.

The device of FIG. 12 and 13, an axisymmetric configuration can also be given, like that of the device shown in FIGS. 8 and 9. In addition, the shape of the device, whether it is axisymmetric (round) or rectangular, can be such that the air flow is deflected not at almost 90 ^about , but at a smaller angle, for example, as in the devices shown in figures 1 and 2, or 3 and 4.

 It is clear from the foregoing that a device in which the surfaces of the targets are superimposed on the inner surface of the channel walls or are located very close to it does not necessarily require additional target electrodes in the middle of the channels, nor the presence of additional electrode elements 10. In addition, the target surfaces on the walls of the channels or located very close to them, can also be used in other embodiments of the invention, such as, for example, the options shown in FIG. 1-10. As mentioned, in this case it is not necessary to ground the targets, but in accordance with another option, it can be connected to a potential different from the potentials of the Earth, and in this case the channel walls must of course be electrically isolated.

 It is also understood that the target electrodes of the device in accordance with the invention may have configurations other than those described and shown. For example, targets do not have to have surfaces running parallel to the side walls of the air channels. In devices in which the air channels have a rectangular cross-section, for example, as the channels of the options shown in FIGS. 1, 2 or 4, 5, or target 1, the targets can have flat electrode elements located perpendicular to the side walls of the air channels, each channel may have one or more electrode elements parallel to each other. In the case of devices made in accordance with, for example, FIG. 1, 5 and 11, such alternative target electrodes will be parallel to the plane of the figures.

 In order to enable the purification of the air flowing through the device made in accordance with the invention, not only from the aforementioned aerosol pollutants, but also from gaseous pollutants, the inner surfaces of the walls 5, the housing 1, which form the channels 6 and 7, can be coated with a layer of chemically active substance that will absorb or catalytically decompose gaseous pollutants of concern. Since the walls 1 and 5 of the device in accordance with the invention can be electrically grounded, it is also relatively easy to cool or heat these walls in order to change the temperature of the air passing through the device.

 As mentioned, the corona discharge at the corona electrode causes the formation of gaseous substances (in particular, ozone and nitrogen oxides), which have a harmful and irritating effect on people nearby, and whose concentration in the ambient air should not exceed certain limit values where people are . The device in accordance with the invention allows to capture and make harmless a significant part of these harmful gases due to the presence of the separation wall 5, located opposite the inlet 2, with the hole 9, located axially opposite the corona electrode K and having a configuration and size, like the corona electrode, as shown as an example in Fig.9. The part of the air flow that passes in the immediate vicinity of the corona electrode and which contains the bulk of the harmful gases generated by the corona discharge will pass through this hole 9. The air passing through the hole 9 can be trapped from the rear side of the separation wall 5, as a result whereby the harmful gases carried by said air can be made safe. This can be done by releasing this air into the atmosphere outside the building or by passing air through a suitable filter, in which harmful gases are absorbed or catalytically decomposed into a safe form. Such a filter can be located in the space behind the wall 5, i.e. behind the hole 9. It is clear that this design can be used in all other embodiments of the invention, for example in the variants shown in figures 1-4, 10, 11 and 12.

 In FIG. 13 and 14 show, by way of example, embodiments in which a portion of the air stream saturated with harmful gases is diverted from a region immediately adjacent to the corona electrode as described above.

 The device shown in FIG. 13 is also configured as the device shown in FIGS. 1 and 2, but with the difference that the target in the embodiment shown in FIG. 13, contains electrode surfaces M located on the inner surfaces of the side walls of the channels 6 and 7, and the housing 1 and the separation wall 5 are electrically isolated. In the dividing wall 5 there is an opening 9 located opposite the corona electrode K, the shape and size of which corresponds to the shape and size of the corona wire electrode K. The part of the air that passed in close proximity to the corona electrode K and, therefore, containing harmful gases generated as a result of corona discharge , will pass through the opening 9. Thus, this part of the air will flow into the space located behind or inside the separation wall 5, and can be cleaned of the mentioned s harmful gases by means of a suitable filter 11.

 The flow of part of the air saturated with harmful gases into the hole 9 is ensured by the fact that the electrode surfaces M of the targets in this embodiment are relatively close to the hole 9.

 Fig. 14 shows, by way of example, a device of the same configuration as the device shown in Figs. 3 and 4, except that the air channels 2, 6 and 7 in the embodiment shown in Fig. 14 have a rectangular cross-section and a corona the electrode K is therefore made in the form of a wire. For the same reason, targets M in the embodiment of FIG. 14 have the form of flat and thin electrode elements. As described, the separation wall 5 is provided with an opening 9 located axially opposite the corona electrode K and having a shape and size similar to that of the corona electrode. Part of the air passing in close proximity to the corona electrode K and, therefore, carrying harmful gases generated as a result of corona discharge will pass through the opening 9. These harmful gases can be removed by passing the said part of the air passing through the opening 9 through a suitable filter as described. Since the dividing wall 5 in this embodiment is electrically conductive and grounded, the part of the wall 5 located closest to the hole 9 will attract a certain small corona discharge current when the distance between the hole 9 and the corona electrode K is properly designed for this. This corona discharge current effectively facilitates the movement of the part of the air closest to the corona electrode through the opening 9. Behind the hole 9, an additional thin electrode element 11 can be installed and connected to the potential of the same sign as the potential of the corona electrode K. This electrode element 11 forms, together with a grounded dividing wall 5, a condenser separator in which aerosol pollutants present in the air flowing through tverstie 9. In this case, the contaminants deposited on the partition wall 5. Thus, such an aerosol contaminants do not allow to enter, contaminating it, a filter is used in order to make safe the harmful gases engendered by the corona discharge.

 A number of devices in accordance with the invention can be combined into one large unit.

 So, figure 10 shows an example illustrating a variant of two or more devices of the type shown in figures 2 and 3, placed axially in one line for passing through them the same air flow. An advantage of such a device is that the dividing wall 5, the outer surfaces of which can be electrically conductive and the internal electrically isolated, will effectively shield the corona electrode K located behind it, effectively preventing unnecessary flow of ion current in the upstream direction.

 In Fig.11 shows two devices shown in Fig.5-8, located adjacent to each other and having inlet openings facing in opposite directions. This combination of device can also be implemented using the embodiment of the device shown in FIG.

 The invention is not limited to the described and illustrated examples of options for its implementation, that the shown and described options can be changed within the scope of the invention and that several devices in accordance with the invention can be combined into an enlarged unit for air treatment.

Claims (18)

 1. DEVICE FOR TRANSPORTATION AND PREFERREDLY SIMULTANEOUS CLEANING OF AIR, containing a corona electrode and at least one target electrode, installed with a gap to the corona electrode, connected to the corresponding terminals of the DC source, the voltage of which and the configuration of the corona electrode are selected from the condition of the possibility of occurrence causing corona ions to form at the corona electrode, and a hollow body formed by walls and having an inlet, the center of which is located on the axis of symmetry of the housing and in which the specified corona electrode is mounted, made needle-shaped or wire-shaped and located respectively along the axis of symmetry or along a line that is perpendicular to the axis of symmetry of the housing, the target electrode being located in the housing symmetrically to the specified axis straight lines drawn between the corona electrode and the part of the target electrode closest to it form an angle α, characterized in that, in order to increase the efficiency of transport processes For simultaneous cleaning and air purification, the casing is configured in such a way that it allows the outward air flow path to deviate behind the inlet with a radial or angular displacement in the direction of at least one target electrode with the formation of at least one air channel, and in each of the air channels the corresponding target electrode is located, and the air channel is displaced relative to the axis of symmetry of the housing, resulting in an obstacle for a rectilinear escheniya at least most of the air in the direction of the symmetry axis of the airflow passage from the inlet to the air passage. 2. The device according to claim 1, characterized in that the angle α formed by the lines drawn between the corona electrode and said at least one target electrode is at least 60 ^° .  3. The device according to claim 1, characterized in that the trajectory of the air flow behind the inlet, in which an extended corona-shaped wire-shaped electrode is mounted, is deflected outward on both sides of the longitudinal axis of symmetry with the formation of two air channels with a rectangular cross section, and the target electrodes installed in these air channels are parallel to the walls of the latter.  4. The device according to claim 3, characterized in that the air channels pass almost parallel to the longitudinal axis of symmetry.  5. The device according to claim 3, characterized in that the air channels pass in almost symmetrically diverging directions relative to the axis of symmetry. 6. The device according to p. 5, characterized in that the diverging directions of the two air channels form an angle between themselves, which practically coincides with the angle α.
7. The device according to claim 3, characterized in that the two air channels diverge in mutually opposite directions almost perpendicular to the axis of symmetry.  8. The device according to claim 1, characterized in that the path of the air flow behind the circular inlet is deflected conically with respect to the axis of the inlet in the form of an air channel with conical walls having an annular cross section and coaxially surrounding the specified axis, in addition, the electrode the target located in the specified air channel is made with an annular cross section.  9. The device according to claim 1, characterized in that the air channel in which the target electrode is located and which has an annular cross section passes almost parallel to the axis of symmetry.  10. The device according to claim 8, characterized in that the direction in which the air channel passes practically coincides with the direction from the corona electrode to the target electrode.  11. The device according to claim 8, characterized in that the air channel extends radially outward in a direction almost perpendicular to the axis of symmetry.  12. The device according to claim 3, characterized in that each of the target electrodes contains a thin electrode element located parallel to the walls of the corresponding air channel and almost in the middle between them.  13. The device according to claim 9, characterized in that the target electrode is cylindrical and is located coaxially with the walls of the air channel of circular cross section and almost in the middle between them.  14. The device according to claim 8, characterized in that the target electrode contains a thin, truncated cone-shaped electrode element located parallel to the walls of the air channel practically in the middle between them.  15. The device according to p. 11, characterized in that the target electrode has a flat annular configuration and is located parallel to the walls of the air channel and almost in the middle between them.  16. The device according to p. 12, characterized in that each of the thin target electrodes extends for most of the length of the corresponding air channel in the direction of air flow.  17. The device according to clause 16, wherein the parts of the target electrodes closest to the corona electrode are electrically conductive or semiconducting and connected to one of the terminals of the DC voltage source, and the rest, the majority, of the target electrodes are made of material with high resistivity and preferably antistatic.  18. The device according to p. 3 or 8, characterized in that the target electrodes have an electrically conductive or semi-conductive surface located in close proximity to the inner surfaces of the walls of the air channels in which the target electrodes are located, or on these surfaces.  19. The device according to claim 1, characterized in that the wall of the housing located opposite the inlet is made with a hole located downstream of the air from the corona electrode and designed to pass through it an air stream coming in close proximity to the corona electrode and containing harmful gases formed by corona discharge, said hole being made with a cross-sectional area smaller than the cross-sectional area of the inlet.

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