RU188607U1 - ELEMENT OF SEDIMENTARY ELECTRODE ELECTROFILTER - Google Patents

Abstract

The proposed element of the precipitating electrode of the electrostatic precipitator relates to the field of dry electrical gas cleaning from dust and can be used in the power industry, ferrous and nonferrous metallurgy, the building materials industry, etc. The objective of the proposed utility model is to increase the efficiency of dust collection by increasing the magnitude of the electric field near the precipitating surface , which contributes to an increase in the drift velocity of dust particles towards the precipitation surface. At the same time, the secondary entrainment of trapped dust decreases during regeneration of the precipitation electrode. The task is solved due to the fact that the surface of the precipitating electrode element is made in the form of a cylindroid by moving a straight line along two parallel curved guides, having the form of a semicircle, semi-ellipse or other geometric lines combined in alternating curves into continuous curves. Moreover, the radius of the semicircles has a size of curvature from 8 to 32 mm, half-ellipses have a curvature of small radius from 4 to 16 mm, a curvature of a large radius from 8 to 32 mm. The width of the element has a size of from 0.5 to 1.0 meters, a height of up to 24 meters, the thickness of the manufacturing material is from 0.5 to 2.5 mm. Fastening to the suspension beams is carried out in places where the side parts of the elements are lined up with each other along the entire field length and separately at the beginning and end of the field of the electrostatic precipitator. Calculations showed that the electric field increases above 10 kV / cm with a standard value of 3.6 kV / cm. The view of the cylindroid surface of the element ensures the strength and rigidity of the structure. The secondary dust loss decreases during regeneration of the precipitation electrode. Due to the proposed element of the precipitation electrode, a perfect innovative dust collection technology has been created.

Description

The proposed element of the precipitating electrode of the electrostatic precipitator relates to the field of dry electrical gas cleaning from dust and can be used in the power industry, ferrous and nonferrous metallurgy, the building materials industry, etc.

A known element of the precipitation electrode, which is made in the form of a complex broken surface, in the middle part of which is a corrugated part with different heights located axisymmetrically relative to the center of gravity of the profile. (Utility model RU 134081. Published 10/11/2013 Byul. No. 31).

The disadvantage of the known S-shaped element of the precipitation electrode is that the complex broken surface of the element provides the magnitude of the electric field near only 3.6 kV / cm (Levitov V. Smoke electrostatic precipitators. M. Energiya. 1980), and how It is known that the drift velocity of dust particles toward a settling surface depends on the electric field intensity. There is also an increased entrainment of trapped dust from the flat surface of the element when the element is regenerated from trapped dust. In addition, due to the presence of sharp edges of the bends of the corrugations and the bends of the end sections, electrical breakdowns of the interelectrode gap occur in these places.

The proposed utility model is based on the task of developing a new element of a precipitation electrode, the design of which will provide a sharp increase in the electric field strength near the precipitation surface. It is known that the drift velocity of charged dust particles toward the precipitation surface depends on the electric field intensity. The drift velocity is proportional to the product of the magnitude of the electric field in the middle part of the interelectrode gap by the magnitude of the electric field strength near the precipitating surface. With an increase in the electric field strength near the precipitation surface, the drift velocity increases. The increase in the drift velocity of dust particles according to the Deutsch law entails a sharp increase in the degree of dust collection of the electrostatic precipitator. In addition, the problem is solved to reduce the secondary entrainment of collected dust during the regeneration of electrodes, since this effect greatly affects the degree of dust collection.

The tasks are solved by the fact that the surface of the element of the precipitation electrode is made in the form of a cylindroid, which is created by moving a vertical straight line along two horizontal parallel curved guides, each of which consists of alternating semicircles and straight lines joined by segments. At the same time, in order to impart rigidity to the structure, the thickness of the fabricated material is from 0.5 to 2.5 mm (see Fig. 1). The use of such a precipitation surface in the form of a cylindroid, in contrast to the complex broken surface of the analog, provides accurate geometrical dimensions along the entire length and width of the proposed element of the precipitation electrode, which affects the preservation of the interelectrode gap and an increase in the operating voltage of the electrostatic corona electrodes. Material manufacturing element can be any electrically conductive with a thickness of from 0.5 to 2.5 mm, depending on the mechanical strength and resistance to dynamic loads during regeneration from trapped dust.

The use of guides in the form of semicircles is of great importance for increasing the intensity of the electric field near the precipitating surface. The calculations (see Appendix) show that on the surface of the semicircles the field strength increases 3 or more times and reaches values up to 10 kV / cm and more, depending on the radius of curvature. This is explained by the fact that any uneven surface concentrates the lines of force of the electric field, and the smaller the radius of curvature, the greater the concentration of lines of force, which means that the electric field is higher. For example, near the corona electrode, in which the curvature of the needle point is possible to 0.1 mm, the field strength increases to a corona discharge. Near the precipitating "S" shaped electrode at the points of the bend, the radius of curvature is on the order of several millimeters, which causes a breakdown of the interelectrode gap. In the proposed element of the precipitation electrode, the radius of curvature of the semicircles is the value in the optimal interval from 8 to 32 mm. In this interval of sizes, the formation of a breakdown is excluded, and the electric field intensity is the highest.

The zones between the semicircles, the so-called “dead zones”, are used to collect trapped dust and send dust to the electrostatic precipitator bin. In the "dead zones" there is no movement of the dust-gas flow along the precipitation electrode. When shaking, the agglomerates of the collected dust under the force of their gravity descend into the hopper of the electrostatic precipitator. If part of the dust re-enters the gas stream, then in the next deposition zone it is again captured and shaken off into the bunker. Such zones are located along the entire length of the field of the electrostatic precipitator in turn, this is a sharp decrease in secondary entrainment.

In the proposed element of the precipitation electrode, the width of the element is set from 0.5 to 1.0 meters, depending on the possibility of its manufacture in a rolling mill or on a press. Allowable height is limited to 24 meters. The increase in further height is associated with an increase in the dimensions of the electrostatic precipitator itself, installation conditions and operating conditions.

In the proposed element of the precipitating electrode there are no connecting side parts. To combine each individual elements in the plane of the precipitation electrode, the method of overlapping the side portions of each other is applied. In order to fasten them, the suspension plates are installed at the interface and attached to the suspension beams along the entire length of the electrostatic field. This ensures the rigidity of the suspension and optimal regeneration conditions for trapped dust by means of a vertical shock effect of shaking mechanisms from top to bottom.

The essence of the utility model is explained using the drawings. They schematically depict:

FIG. 1 Element of a precipitation electrode in the form of a cylindroid, obtained by moving a straight vertical generatrix along two parallel horizontal curved guides.

FIG. 2 Sections of the precipitating electrode element of the electrostatic precipitator.

FIG. 3 The distribution of the electric field near the precipitating surface of the element.

FIG. 1 shows the element of the precipitation electrode in the form of a cylindroid. The vertical straight line generator "1" is parallel to the plane of the precipitation electrode. Horizontal curves guides "2" consist of alternate semicircles and straight lines. The direct generator "1" moves along the two curves of the guides "2" and creates a plane of the element of the precipitation electrode in the form of a cylindroid.

FIG. 2 shows a section of a precipitating electrode element, namely: semicircles “1”, mirror-reflected semicircles “2” with radii of curvature R in size from 8 to 32 mm, straight lines “3” combined with connecting segments “4” with radii of curvature not less than 8 mm . The claimed geometric parameters of the element of the precipitation electrode are optimal for this design solution in accordance with the calculations (see Appendix).

FIG. 3 shows the results of the calculation of the distribution of the electric field strength and the distribution of the power lines near the element of the precipitation electrode. Charged dust particles move to the precipitating surface of the element of the precipitation electrode with the drift velocity under the action of the Coulomb force along the electric power lines. The drift velocity of dust particles is proportional to the magnitude of the electric field strength in the interelectrode gap multiplied by the electric field strength near the settling surface (IP Vereshchagin, VI Levitov, G.Z. Mirzabekyan, MM Pashin. Fundamentals of Electrogasdynamics of Disperse Systems. M., "Energy", 1974). Getting into the zone of increased tension near the precipitation surface, dust particles acquire a greater drift velocity and more intensively settle on the precipitation surface. Tension near semicircles is up to 10 kV / cm (Fig. 3). This means that the proposed precipitation element increases the value of tension in the dust deposition zone by three or more times compared to the analogue, the drift velocity of the dust particles increases by more than 9 times, and the efficiency of the electro-precipitator dust collection increases dramatically.

FIG. 3 for clarity, a picture of the influence of acute angles on the surface of the element of the precipitating electrode is shown. In the areas of the bend of the surface of the semicircles and straight lines, local points of increasing tension are visible, which means that a breakdown of the interelectrode gap will occur at these points, which will entail a decrease in the efficiency of dust collection. To avoid this phenomenon, all bends must have a radius of segments of at least 8 mm, as shown in FIG. 2 "4". The pockets of the “dead zones” 2 and 3 collect the collected dust. In these zones there is an electric field of up to 3.6 kV / cm near straight lines, which also captured charged dust particles. In these zones there is no longitudinal movement of the gas flow. During regeneration, detached agglomerates of trapped dust fall in these “dead zones” into the electrostatic precipitator bunker bypassing the gas stream. This dramatically reduces secondary dust entrainment.

Using the proposed design element of the precipitation electrode allows to increase the degree of gas cleaning from dust in the electrostatic precipitator due to the increase in the electric field strength near the precipitating surface. Calculations showed that the electric field strength rises above 10 kV / cm with a standard value in the interelectrode gap of 3.6 kV / cm. The view of the surface of the element of the precipitation electrode in the form of a cylindroid ensures the strength and rigidity of the structure. The secondary dust loss decreases during regeneration of the precipitation electrode.

Placing the semicircles in the opposite direction with respect to straight sections increases the rigidity of the structure, and the equal size of these straight sections ensures the symmetry of the element of the precipitation electrode along the entire length of the vertical straight line. The height of the element of the precipitation electrode over 24 meters is practically not feasible. The larger size leads to a sharp increase in operating costs, creates difficulties in installing the electrode system of the electrostatic precipitator. The boundary conditions for the thickness of the element of the precipitation electrode are selected from the conditions of the material of their manufacture: the greater the Hooke value in tension, the thinner the element of the precipitation electrode. The optimal value is calculated by known methods at the design stage of the electrostatic precipitator.

The proposed elements are assembled in the plane of the precipitation electrodes by the method of lining the elements on each other along the entire length of the field of the electrostatic precipitator, moreover, the attachment plates to the suspension beams are installed in known places in the lining places. This achieves the best conditions for the transmission of the pulse of the shaking mechanism during the regeneration of the precipitation electrode.

Due to the proposed element of the precipitation electrode, a perfect innovative dust collection technology has been created.

Claims (5)

1. Element of the precipitating electrode of the electrostatic precipitator, made in the form of a complex broken surface, characterized in that the surface of the element of the precipitating electrode is made in the form of a cylindroid, which is created by moving a vertical straight line along two horizontal parallel curved guides, each of which consists of alternate semicircles and straight lines lines connected by segments. 2. Element of the precipitating electrode of the electrostatic precipitator according to claim 1, characterized in that the radius of the semicircles of the curved guides have a curvature value from 8 to 32 mm, and the radius of the segments is at least 8 mm. 3. Element of the precipitation electrode of the electrostatic precipitator according to claim 1, characterized in that the length of the element of the precipitation electrode (the length of the horizontal curved guides) is from 0.5 to 1.0 m, the height of the vertical straight generatrix reaches values up to 24 m, the thickness of the element is equal to 0.5 to 2.5 mm. 4. Element of the precipitation electrode of the electrostatic precipitator according to claim 1, characterized in that at each element of the precipitation electrode there are at least 3 semicircles of the opposite direction, and the size of the length of each straight-line portion of the curved guides is the same. 5. Element of the precipitating electrode of the electrostatic precipitator according to claim 1, characterized in that in places where the plates of elements overlap each other along the entire length of the electrostatic field, attachment plates to the suspension beams are installed and separately installed at the beginning and end of the extreme elements of the precipitating electrode of the electrostatic field.

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