RU2466771C1 - Electric cleaner with pairwise connection of electrodes to source of energy - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device comprises a body and electrodes with holes, which are connected to a source of high DC voltage in pairs: two adjacent electrodes are connected with a positive terminal of a power source, another two - with a negative terminal, and so on till the last electrode. The first pair of electrodes, counting from the input into the electric cleaner, is connected to the positive terminal of the power source. Between unipolar electrodes there are circular gaskets arranged from any material to form a required gap between them. Between heteropolar pairs of electrodes there are circular gaskets from a dielectric material to prevent an electrical breakthrough. Each electrode comprises one hole arranged near the edge, besides, during assembly, electrodes are arranged so that holes in adjacent electrodes are diametrically opposite.

EFFECT: increased efficiency of mechanical particles deposition onto negative electrodes due to increased quantity of ions generated from mechanical particles of contaminants.

2 dwg

Description

The invention relates to a device for cleaning dielectric liquids and gases from mechanical impurities.

Known electric cleaner of dielectric liquids [1], comprising a housing and precipitation electrodes, made in the form of metal plates with slots forming channels for the passage of fluid, and equipped with partitions from a dielectric material. Precipitation electrodes are connected to a constant high voltage source with alternating sign of potential.

The disadvantage of this cleaner is that connecting the electrodes with alternating sign of the potential does not allow to achieve the possible cleaning efficiency of the dielectric medium.

Known electric cleaner of dielectric liquids and gases with non-parallel electrodes [2], including a housing and precipitation electrodes, made not flat, but in the form of a cone. The electrodes are alternately connected to a high voltage source.

The disadvantage of this electric cleaner is the inability to achieve the desired efficiency of its work.

Closest to the invention is an electric cleaner of dielectric liquids (and gases) with a one-sided arrangement of holes in the electrodes [3], including a housing and precipitation electrodes with one hole located close to the edge of the electrode. During assembly, the electrodes are positioned so that the holes in the adjacent electrodes are diametrically opposed. The electrodes are connected to a high voltage source with alternating sign of potential.

The disadvantage of this electric cleaner is that it does not realize the possible performance and degree of purification of the dielectric medium.

The purpose of the invention is to increase the efficiency of the electric cleaner.

The essence of the invention lies in the fact that the electrodes of the electric cleaner are connected to a constant high voltage source in pairs: two adjacent electrodes are connected to the positive terminal of the power source, the next two to the negative terminal, the next two again to the positive terminal, the next two again to the negative terminal and etc. to the last electrode, and the first pair of electrodes, counting from the entrance to the electric cleaner, is connected to the positive terminal of the energy source, and between the electrodes having the same potential sign, ring gaskets of any material are installed to provide the required distance between these electrodes, but between the pairs of electrodes with the same sign of electric potential, ring gaskets made of dielectric material are installed, to prevent electrical breakdown between adjacent ones, they are oppositely charged mi pairs of electrodes.

Such a connection of the electrodes with a voltage source increases the number of impurity particles charging in the interelectrode space.

Currently, the interelectrode space is formed by positive and negative electrodes. When the flow of the medium being cleaned in the interelectrode space moves, some particles touch the positive electrode (connected to the positive terminal of the energy source), while others touch the negative electrode. Particles of pollution, like all material things, are composed of atoms and molecules. Atoms (charged particles) turn atoms and, rarely, molecules. Therefore, it is assumed that when the particles touch the electrodes with pollution particles, both positive and negative ions are formed from the latter. However, it is not. Positive ions in the region adjacent to the positive electrode are formed quite easily. For their formation, it is necessary to tear off the electron from the outer orbit of the atom. This happens when touching the particles of contamination of the positive electrode, on which there is a lack of electrons. The energy of the electric field on the electrode (from 5 to 25 kV) is quite sufficient to detach the electron from the atom (the energy of the electric field is higher than the ionization potential of the atom).

However, for the formation of negative ions (electron attachment to an atom) special conditions are required. The formation of negative ions is carried out as follows [4]: first, in the case of dissociative attachment of an electron to an atom. But this requires sufficiently high electron speeds, which is not in the electric cleaner; secondly, in the case of radiative attachment of electrons to an atom and a molecule, which again is not in the interelectrode space; thirdly, the attachment of an electron to a molecule is possible in triple collisions, which again is not on the negative electrode; fourthly, the formation of negative ions in a gas discharge is possible, but a gas (or other) discharge in the interelectrode space is not allowed; fifthly, draining of negative ions is possible from sharp surfaces, but the electrodes are flat and there are no pointed surfaces in the electric cleaner. Also, the formation of negative ions is impossible for atoms with filled outer shells, in particular for alkaline earth elements and inert gases.

Thus, it turns out that in the interelectrode space enclosed between the positive and negative electrodes, mainly only positive ions are formed. Negative ions either do not form at all or are formed in very small quantities. Moreover, if the flow is laminar (low flow rate of the medium being cleaned), then the formation of ions from neutral impurity atoms occurs only in the zone adjacent to the surface of the positive electrode (positive ions are formed). The remaining region of the interelectrode space, including the surface of the negative electrode, does not participate in the formation of ions, i.e. is a non-working area. If the flow of the cleaned medium in the interelectrode space is turbulized (mixed) with an increase in its speed, when the flow rate of the cleaned flow increases, some of the positive ions formed can get (attract) to the negative electrode and settle on it. Then a smaller number of ions will enter the next interelectrode space. In general, the speed of cleaning a dielectric medium depends on the number of ions formed in the interelectrode space: the more they are formed, the more particles of impurities will settle on the electrodes, the faster and more completely the dielectric medium will be cleaned. Neutral particles do not settle on the electrodes. And this will ensure an increase in the efficiency of the electric cleaner. Therefore, the authors propose to separate all the electrodes, as it were, into separate sections, which are interelectrode spaces. But each interelectrode space is formed by electrodes connected to one sign of the potential of the electric power source, and adjacent interelectrode spaces are connected to different poles. Then, in the interelectrode space formed by the positive electrodes, the amount of positive ions will appear more than twice as much as in existing electric cleaners (it does not matter what sign the ions are formed to clean from pollution). And in the next interelectrode space, these positive ions will be attracted by negative electrodes and deposited on them. The processes of ion formation and their deposition will occur more actively than now.

Comparative analysis allows us to conclude that the proposed electric cleaner differs from the prototype in that the electrodes in it are connected to a high voltage source, not with alternating the potential sign, but in pairs:

two adjacent electrodes are connected with a positive sign, the next two with a negative sign, etc. all electrodes. Moreover, the first two electrodes, starting from the input, are connected to the positive sign of the potential. Thus, the proposed technical solution meets the criterion of "novelty."

Analysis of the known technical solutions (analogues) in the studied area allows us to conclude that there are no signs in them that are similar to the essential distinguishing features in the claimed device, and to recognize it as meeting the criterion of "significant differences".

The use of all new features allows one to significantly increase the formation of ions from mechanical particles of contaminants and their deposition, i.e. increase the efficiency of cleaning dielectric media.

Figure 1 presents a General view of the cleaner in longitudinal section, and figure 2 is a cross section and a diagram of the formation of ions in the interelectrode space, with the existing circuit for connecting electrodes to a high voltage source. The electric cleaner consists of a housing 1, Fig. 1, covers 2 and 9 along the ends of the housing, into which an input 10 and an output 4 fittings are screwed. At the ends of the electrode package, under the covers, there are restriction plates 3 with holes made of dielectric material and having a greater thickness on the periphery, on the one hand, than on the rest of the area. Inside the housing are electrodes 5, made in the form of round metal plates with holes 12 at the edges of these plates, figb. Between adjacent electrodes having the same polarity, annular gaskets 6 of dielectric (or any other) material are placed to provide the required interelectrode distance. Since neighboring electrodes have the same electric polarity, the interelectrode distance can be reduced, compared with the existing one, to create a stronger electric field in it, without fear of electrical breakdown between these electrodes. And between adjacent pairs of electrodes are gaskets 7 of dielectric material with holes. Along the perimeter, these gaskets have a greater thickness than in the rest, so that there is a distance (gap) between the gasket plane and the nearest electrode plane for the flow of the medium to be cleaned. The thickness of the gaskets 7 (around the perimeter) is chosen such that during the operation of the cleaner there is no electrical breakdown. The thickness of these gaskets does not affect the operation of the electric cleaner, so it can be taken with a margin (slightly thicker than necessary to ensure the absence of electrical breakdown). A constant high voltage source 8 is connected to the electrodes as follows. The first two electrodes, if counted from the entrance to the cleaner, are connected to the positive terminal. Because Since the particles in the medium to be cleaned are mostly neutral, they must first be converted into ions so that they can subsequently settle on the opposite charged electrode. And above, we noted that ions are formed only on the positive electrode (in the vast majority), then the first pair of electrodes must be positively charged. The second pair of electrodes is connected to the negative terminal, the third pair to the positive terminal, the fourth pair to the negative terminal, etc. to the last electrode. The number of electrodes must be a multiple of four, so that an integer number of positively and negatively charged pairs of electrodes can be formed from them. Between the cleaner body and the electrode stack there is a gasket 11 made of dielectric material, which prevents a short circuit between the body and the electrodes, FIG. 1 and FIG. 2b. On figa schematically shows two adjacent electrodes of the prototype. All interelectrode space can be divided, conditionally, into three areas: I, II, III. The first region is that which is adjacent to the surface of the positive electrode and in which ions (positive) are formed. The second region occupies the volume in the center of the interelectrode space and corresponds to the minimum value of the electric field strength. From this area, a particle of contamination can begin to move both to the positive electrode and to the negative, or it may not start. The third region is adjacent to the negative electrode. But, as we noted above, there are no conditions for the formation of ions, and particles of contamination float along the surface of this electrode, touch this surface, but no ions appear, i.e. the formation of ions occurs only at the positive electrode, in this case in the first region. The other two areas are inoperative from the point of view of ion formation.

The proposed electric cleaner works as follows. Through the nozzle 10 in the cover 9, the dielectric fluid or gas to be cleaned flows into the housing 1. High voltage of constant polarity is preliminarily applied to the electrodes 5. After the nozzle 10, the medium to be cleaned flows through the holes in the restriction plate 3, washes the outer surface of the first electrode 5 and, through a hole in it, located close to the edge, enters the interelectrode space between the first and second electrodes 5, flows between them and, through the hole in the second electrode, located diametrically opposite to the hole in the first electrode, flows from the interelectrode space of the first pair of electrodes. Since the first and second electrodes are connected to the positive terminal of source 8, and the distance between the electrodes is chosen to be minimal (so that there is no resistance to the movement of the medium being cleaned), under the influence of an electric field in almost the entire volume of the interelectrode space, and not only in the region adjacent to the positive electrode positive ions are formed. The same ions are formed when washing the outer surfaces of both electrodes. The formed ions of mechanical impurities, together with the flow of the medium to be cleaned, flow further, through the holes in the partition 7 and the hole 12 in the third electrode, into the interelectrode space 3 and 4 of the electrodes. Since these electrodes are connected to the negative terminal of the energy source 8 and the distance between them is also minimal, positive ions will be attracted to the negatively charged electrodes and settle on them. Since the flow of the medium being cleaned moves rather quickly, in the first stage of purification, conditionally formed by the first four electrodes, not all particles of contaminants have time to turn into ions and settle on negative electrodes. Therefore, the remaining particles of impurities, together with the flow, from the interelectrode space of 3 and 4 electrodes, through the holes in the 4 electrode and the next partition 7, enter the interelectrode space of the electrodes 5 and 6 (through the hole in the fifth electrode). Since these electrodes are connected to the positive terminal, between 5 and 6 electrodes positive ions will again form from the remaining neutral impurity particles, which will then enter the interelectrode space of 7 and 8 electrodes connected to the negative terminal of source 8 and settle on them. And so the process of extracting mechanical particles from the medium to be cleaned will be repeated at subsequent stages of cleaning the electric cleaner, each of which consists of four electrodes (two positive and two negative). Since the electric field strength acting on the mechanical particles of impurities in the interelectrode space increases due to a decrease in the interelectrode distance, the rate of formation of ions on positive electrodes and their deposition on negative electrodes also increase. This increases the efficiency of the electric cleaner. In addition, the proposed electric cleaner practically eliminates electrical breakdowns between the electrodes that occur in existing electric cleaners as pollution accumulates, and power supply units that no longer work.

Information sources

1. Patent for the invention of the Russian Federation No. 2377072 "Electric cleaner of dielectric liquids (and gases) with rounded holes in the electrodes."

2. Patent for the invention of the Russian Federation No. 2363541 "Electric cleaner of dielectric liquids and gases with non-parallel electrodes."

3. Patent for the invention of the Russian Federation No. 2385176 "Electric cleaner of dielectric liquids (and gases) with one-sided arrangement of holes in the electrodes".

4. Smirnov B.M. Negative ions. - M., 1978.

Claims (1)

An electric cleaner with connecting electrodes to an energy source, including a housing and electrodes with a one-sided arrangement of holes, between which partitions are placed, characterized in that the electrodes are connected to a constant high voltage source in pairs: two adjacent electrodes are connected to the positive terminal of the electric source, the next two to the negative terminal, the next two again with the positive terminal, the next two again with the negative terminal, etc. to the last electrode, and the first pair of electrodes, counting from the entrance to the electric cleaner, is connected to the positive terminal of the energy source, and between the electrodes having the same potential sign, ring gaskets of any material are installed to provide the required distance between these electrodes, but between the pairs of electrodes with the same sign of electric potential, ring gaskets made of dielectric material are installed to prevent electrical breakdown between adjacent ones, oppositely charged and pairs of electrodes.

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