RU2009716C1 - Electric filter - Google Patents

Abstract

FIELD: filtering devices. SUBSTANCE: filter has a deposit cassette which, in turn, has deposit electrodes mounted on electric insulators, potential electrodes made in the form of closed cavities. The cavities are formed by a plane-parallel bases interconnected by equidistant side surfaces which are perforated with louver holes. The rows of formed holes are parallel to the bases. A charging cassette is connected to the deposit cassette, a collector electrode of the charging cassette is made in the form of a conical surface and has members screening a corona-forming electrode mounted on two electric insulators. EFFECT: improved structure. 4 cl, 7 dwg

Description

 The invention relates to techniques for the electrical cleaning of gases from suspended solids - solid and liquid particles in a gas, in particular to dual-zone electrostatic precipitators with separate charging and deposition zones of particles, can be used to clean gas from welding aerosol, oil mist formed in mechanical engineering, and for air purification in premises of domestic, public, medical, sports and cultural purposes.

 Known electrostatic precipitator containing separated by electrical insulators, located equidistantly, the precipitation and potential electrodes of the precipitation cassette connected to the charging cassette, equipped with elements of the corona and collector electrodes. The deposition and potential electrodes of the precipitation cassette are made, in the particular case of equidistance, plane-parallel, installed at a distance between the electrode gap. The bases - the ends of these electrodes form the channels of gas entry into the interelectrode space and gas exit. As the gaps become overgrown with suspension, they are washed. The last electrostatic precipitator is closest to the one proposed in terms of technical nature and the achieved effect.

 The disadvantages of the known electrostatic precipitator are that it contains several tens of precipitation and potential electrodes located in the precipitation cassette with the greater accumulated technological error, the greater the number of electrodes. The error in the mutual arrangement leads to a decrease in the degree of gas purification from suspension and an increase in the energy costs of operating the electrostatic precipitator due to the unevenness of the channels for gas passage and their uneven overgrowth with a layer of trapped dust. A significant number of electrodes complicates the design of the electrostatic precipitator and increases manufacturing costs.

 The purpose of the invention is to increase the degree of gas purification from suspension, reducing the cost of manufacturing and operating an electrostatic precipitator.

 This goal is achieved by the fact that in the known electrostatic precipitator, separated by electrical insulators, located equidistant precipitation and potential electrodes of the precipitation cassette, connected to the charging cassette, equipped with elements of the corona and collector electrodes, the equidistant spaced electrodes of the precipitation cassette are made in the form of closed cavities with plane-parallel bases perforated with louvre holes located in equidistant rows at a distance of s slurry deposition on all electrodes.

≅ 80
Отличительные признаки данного технического решения по источникам патентной и научно-технической информации неизвестны, поэтому предложенное устройство соответствует критериям новизны и существенных отличий.L = h ^. S ₁ / S (p-1), where h is the distance between adjacent electrodes;
S is the cross-sectional area of the electrode gap;
S ₁ is the surface area of the precipitation electrode, except the extreme ones, on the surfaces of which the rows are offset relative to each other by the specified distance, and the rows of louvre holes are directed at equal angles to the bases of the electrodes in the range from zero to straight, and the collector electrode of the charging cassette is made in the form of a conical a surface equipped with a slotted flange covering the elements of the corona electrode. The rows of louver openings can be located at an angle from 0 to 90 ° with respect to the bases of the precipitation cassette; the number of rows of louvered holes on the inner electrodes P of the precipitation cassette is equal to the sum of the numbers of rows on the outer electrodes
P = m + n, and the ratio of the surface area of the precipitation electrode to the cross-sectional area of the electrode gap can satisfy the ratio:
30 ≅

≅ 80
Distinctive features of this technical solution by the sources of patent and scientific and technical information are unknown, therefore, the proposed device meets the criteria of novelty and significant differences.

 In FIG. 1 shows a diagram of an electrostatic precipitator; in FIG. 2 is the same, a top view of FIG. 1; in FIG. 3 is a diagram of a charging cassette; in FIG. 4 is a section AA in FIG. 3; in FIG. 5 is a section BB of the charging cassette of FIG. 3; in FIG. 6 is a diagram of a precipitating cartridge with conical equidistant lateral surfaces of the electrodes; in FIG. 7 is a section BB of the precipitation cassette of FIG. 6.

 The electrostatic precipitator consists of a precipitation cassette containing 1 electrodes and 2 potential 3 electrodes mounted on electrical insulators 2 (Fig. 1). A charging cassette is connected to the precipitation cassette, equipped with a corona 4 electrode located on the electrical insulators 5, 6 and collector 7 electrode (Fig. 1, 3-5). The electrodes 1, 3 of the precipitation cassette are made in the form of closed cavities. The cavities are formed by plane-parallel bases 8, 9, common to all electrodes 1, 3. The bases 8, 9 are interconnected by equidistant lateral surfaces.

 Depicted in FIG. 1 equidistant lateral surfaces are cylindrical and form a system of coaxial pipes.

 The equidistant lateral surfaces of the electrodes 1 and 3 are perforated with louvre holes 10, 11.

 The louvre openings 10, 11 are square, rectangular, round, oval or other shape, arranged in equidistant rows. The rows can be directed parallel to the bases 8, 9 (Fig. 1), that is, at a zero angle to the base or perpendicularly (the angle is equal to a straight line), as well as at an angle α ranging from zero to a straight line, however, due to the equidistance of the rows, all angles are each electrode 1, 3 are selected equal to each other.

 The number of rows on the surface of each electrode 1, 3 may be from one or more. The distance between the rows of louvered holes, measured on the surface of the electrodes 1, 3, is L (Fig. 1) - the length of the deposition of the suspension on the precipitation electrodes 1.

L = h ^. S ₁ / S (p-1), where h is the distance between adjacent electrodes;
S is the cross-sectional area of the electrode gap;
S ₁ - surface area of the precipitation electrode;
p is the number of rows of louvered holes on the internal electrodes.

 At the extreme electrodes - internal and external - the rows are offset relative to each other by the same distance L. Thus, at the extreme electrodes - these can be both potential 3 and precipitation 1 - the number of rows of louvered openings is less than on the internal ones. In this case, equality holds: p = m + n, where p is the number of rows on the internal electrodes, m and n are on the two extreme ones.

 The lateral surface can be made in the form of a surface bounding the plane, a cylindrical surface, in particular a straight cylinder, a prism, a direct prism, a pyramid, a truncated pyramid, a round straight cylinder (Fig. 1), a straight cone, a truncated straight cone (Fig. 6) , spherical segment or layer, barrels, etc.

 The charging cassette is installed inside the pipe 12 by the base 13. The collector electrode 7 is made in the form of a conical surface and is equipped with elements that shield the corona electrode 4 mounted on two electrical insulators 5, 6, one of which is made in the form of a ring mounted on the base 13, and the second located at the top of the cone of the collector electrode 7 and is made in the form of a point with a hole in the top. In this hole in the center are connected the elements of the corona electrode 4, made in the form of a thread. The second ends of the elements of the corona electrode 4 are mounted on an insulator 5 located on the base 13.

 The rows of louver holes 10 form the gas inlet channels into the interelectrode gap, and the rows of holes 11 form the gas outlet channels from the electrostatic precipitator according to the arrows.

 Near the base 8, drainage holes can be made in the electrodes 1, 3 (Fig. 1), connected by a water trap to drain the liquid in the event of fog trapping.

 Before operating the electrostatic precipitator, the latter is connected to a power source, while the precipitation 1 and collector 7 electrodes are grounded; potential 3 and corona 4 electrodes are supplied with high voltage, as a rule, different for each type of electrode. In the pipe 12 in the direction of the arrow (Fig. 1) serves the cleaned gas containing a suspension in the form of solid or liquid particles. In the charger, a unipolar corona discharge occurs from the corona 4 electrode to the screen elements of the collector 7 electrode when the power source is turned on. In the corona discharge zone, suspended particles acquire an electric charge. Gas with charged particles through the inlet channels 10 enters each interelectrode gap between the precipitation 1 and potential 3 electrodes. Under the action of the forces of the electrostatic field created by these electrodes, charged particles acquire a drift velocity to the precipitation electrodes and are held on these electrodes by adhesion forces. If the particles are solid, then a layer of trapped particles gradually forms on the surfaces of the precipitation electrodes and the interelectrode gap begins to grow as the layer thickness increases. The growth occurs before the electric breakdown of the gap, after which the electrostatic precipitator loses its working capacity, requires washing the precipitation cassette to remove trapped particles. If the particles are liquid, then the liquid film flows down along the electrodes and is removed through drainage holes and a water seal. The purified gas leaves the electrostatic precipitator through the outlet 11, formed by rows of louvre holes, passing the path L in the electrode spacing equal to the deposition length, determined from the ratio of the product of the gap to the ratio of the gas velocity to the particle drift velocity. Stagnation zones without gas flow are formed near the bases 8, 9, and 13, which protects insulators 2 and 5, 6 from settling of particles, especially since the charge of the particles is opposite to the potential of the electrodes supported by these insulators. The tip of the insulator 6 is also located in the stagnant zone of the gas flow.

 The deposition cassette can have one row of holes on the outer electrodes, therefore, the deposition length is equal to half the circumference of the inner electrode, the location of the holes at an angle α can improve gas distribution over the holes, reduce the speed in the hole. A more uniform distribution of gas along the axis of the precipitation cassette is facilitated by its conical shape.

 In the described electrostatic precipitator, the problem of a substantial increase in the stiffness of the electrodes of the precipitation cassette due to their implementation in the form of closed cavities that limit a certain volume is solved. The volume of the electrodes and the closure of the side surfaces with bases increases the stiffness of the electrodes so much that they can significantly increase their surface and reduce the number of electrodes to two: one precipitating, the other potential. Moreover, by reducing the number of electrodes and increasing their rigidity, it is possible to increase the accuracy of positioning of the electrodes, ensuring the constancy of the electrode gap at any point of the electrodes. This increases the degree of gas purification from suspension.

 In the proposed electrostatic precipitator, the gas inlet and outlet channels are located not at the ends of the electrodes of the precipitation cassette, as in the prototype, but over the entire surface of the electrodes in the form of rows of louvered openings. The more rows of holes or the longer the series of holes, the smaller the number of electrodes in the precipitation cassette. The increase in the surface of the electrodes mentioned above is possible precisely due to the formation of a number of inlet and outlet channels of gas on the side surfaces. Such a gas supply also provides a reduction in hydraulic losses during uniform distribution of gas along the interelectrode gaps due to the selection of the number, shape and size of the louvre holes in the row and the location of the latter relative to the bases, depending on the method of supplying gas to the pipe and the distribution of gas velocities in the cross section of the inner electrode. Thus, in this electrostatic precipitator, the aerodynamics of the apparatus are not related to electrical parameters and can be independently optimized. In particular, by increasing the total cross section of the inlet and outlet channels, hydraulic losses at the gas inlet and outlet can be reduced. The implementation of the charging cassette allows for any form of electrodes of the precipitating cassette to ensure a uniform (identical cross-section) charge of the particles of the suspension. The uniformity of the particle charge and gas velocity in all interelectrode gaps additionally increases the degree of gas purification from suspension. Moreover, this advantage is maintained even when the electrodes are overgrown, since it occurs evenly. In addition, uniform overgrowth of the electrodes increases the operating time until the next rinse after the electric breakdown of the gap, thereby reducing the operating costs of maintaining the electrostatic precipitator. Reduced due to the reduction of hydraulic losses, and energy operating costs.

 Simplification of the design, reducing the number of electrodes to a few (two in the limit), the exclusion from the design of tens and hundreds of connecting parts: bushings, couplers, etc., reduces manufacturing costs.

 Thus, the constancy of the interelectrode gap, providing maximum electric field strength, and the constancy of the gas velocity in the gap provide the highest (ceteris paribus) degree of gas purification from suspension, significantly exceeding the efficiency of the prototype.

≈ 43
Таким образом, выполняется соотношению 30 ≅

≅80 для сочетания оптимальных электрических и аэродинамических параметров электрофильтра, обеспечивающих степень очистки газа от взвеси. (56) Патент ФРГ N 1407496, кл. В 03 С 3/08, 1975.An example of performing an electrostatic precipitator at a flow rate of 1000 m ³ / h. The distance between the electrodes in the precipitation cassette is 7 mm. The cross-sectional area of the electrode gap is 110 cm ² . The surface area of the precipitation electrode 28260 cm ^{2 the} number of rows p = 7. In this case

≈ 43
Thus, the relation 30 ≅

≅80 for a combination of optimal electrical and aerodynamic parameters of an electrostatic precipitator, providing a degree of gas purification from suspension. (56) Patent of Germany N 1407496, cl. B 03 C 3/08, 1975.

Claims (4)

1. ELECTRIC FILTER containing separated electrical insulators, located equidistantly precipitating and potential electrodes of the precipitating cassette, connected to a charging cassette equipped with a corona electrode and a collector electrode, characterized in that, in order to increase the degree of gas purification and suspension, operation of the filter, equidistant electrodes of the precipitating cassette are made in the form of closed cavities with plane-parallel bases and perforated louvred openings located in equidistant rows at a distance L of the suspension deposition length at all electrodes
L = hS ₁ / S (p - 1),
where h is the distance between adjacent electrodes;
S is the cross-sectional area of the interelectrode gap;
S ₁ - surface area of the precipitation electrode;
p is the number of rows of louvered holes on the internal electrodes,
In addition, at the surfaces of which the series are displaced relative to each other by the indicated distance, moreover, the rows of louver openings are directed at equal angles to the bases of the electrodes, and the collector electrode of the charging cassette is made in the form of a conical supporting surface. 2. The electric filter according to claim 1, characterized in that the rows of louvred openings are located in relation to the bases of the precipitation cassette at an angle of 0 - 90 ^o . 3. The electric filter according to paragraphs. 1 and 2, characterized in that the number p of rows of louver openings on the inner electrodes of the precipitating cassette is equal to the sum of the numbers m and n of rows on the outer electrodes
p = m + n.  4. The electric filter according to paragraphs. 1 - 3, characterized in that the ratio of the surface area of the precipitation electrode to the cross-sectional area of the interelectrode gap satisfies the ratio

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