UA70055A - Electrofilter - Google Patents

Abstract

Electrofilter contains housing, inlet and outlet ducts and precipitated electrodes mounted between them in parallel with the gas flow, said electrodes being collected from lamellar precipitated elements fixed in the upper and bottom beams of precipitated electrode, corona electrodes located between them and mounted on supporting frames, which are suspended from the insulators, anvils fixed on the electrodes, hammer mechanisms of the shaking of electrodes, which interact with the anvils, stops and limiters. Precipitated electrodes are sectional on the height, the ends of adjacent sections of precipitated electrodes are equipped with horizontal laths fixed on the lamellar precipitated elements. In this case the laths of sections adjacent along the height are connected together and will form the additional middle girder of shaking of precipitated electrode, which from both ends is equipped with additional stops interacting with additional limiters of the cross travel of precipitated electrode in its average part on the height mounted on the housing, and anvil mounted on one of the ends of the middle girder of shaking. Corona electrodesare sectional, each section is freely mounted on the supporting frames and is equipped with the stops connected with the supporting frames, in this case the smallest distance in the opening between the girder of shaking of precipitated electrode and the ends of the sections of the adjacent corona electrodes and the distance in the opening between the precipitated and corona electrodes are selected from the relationship. Precipitated electrode is gas-permeable and consists of lamellar precipitated elements, executed in the form of profile, cross section of which takes the form of broken Z-shaped line, which consists of three series-connected sections, moreover extreme sections have identical length, they are parallel between them and are located in parallel planes distanced from each other, the average section of broken line connects both extreme sections.

Description

Description of the invention

The claimed invention relates to gas purification in electrofilters and can be used in 2 energy, metallurgy, cement production and other industries.

The famous electrostatic precipitator |Yudashkin M.Ya. Gas capture and purification in ferrous metallurgy, M.,

Metallurgy, 1984. p.197-235), which includes a housing, inlet and outlet nozzles, sediment electrodes installed in parallel inside the housing along the direction of gas movement, equipped with upper and lower beams, between which plate sediment elements are installed and fixed, and the lower the beam is a shaking beam, and the corona electrodes are located in the channels between the sediment electrodes. The removal of dust deposited on the corona electrodes is carried out by tapping the corona electrodes, which are rigidly fixed on the support frames in one or more levels, and the removal of the dust layer from the sediment electrodes installed by the upper beams on the supporting elements of the electrofilter body is carried out by tapping the latter by impact with hammers on the shaking beams, which are fixed in the lower end of 72 sediment electrodes. Limitation of the lateral (relative to the gas flow) movement of sediment electrodes is carried out using limiters, for example, forks fixed on the body of the electrostatic precipitator or its elements, in which the shaking beams of the sediment electrodes are installed with a gap, or the retainers fixed on the shaking beams.

Taking into account practical experience, it is possible to note the following main disadvantages of the mentioned design.

In modern industrial electrofilters, designed to clean large volumes of gas (from 100,000 mU/h to 1,000,000 mZ/h and more), in which it is economically, technically and practically expedient to use electrodes with a height of 7 m to 15 m and more, there are very expensive means of ensuring the technologically permitted tolerances for electrofilters on the decentering of the electrode system, which are determined by the technological process of manufacturing profiled plate elements of sedimentary electrodes, their assembly and mounting, as well as means of ensuring the effective removal of a layer of trapped dust from sedimentary electrodes, "especially with the upper, farthest from the shaking beam, part of the sedimentary electrodes, and more effective cleaning of the dust layer of the coronal electrodes.

The decrease in the efficiency of the electrofilters, which is associated with the decentering of the electrode systems, is explained by the norms in force in world practice for tolerances and landings on rolled steel in the manufacture of profiled plate elements of sedimentary electrodes: deviation from the plane, incl. sabre-likeness, and c) propeller (twist), etc., as a rule, should not exceed 0.195 of the length of the product. Taking into account the allowed tolerances for assembly and installation, including installation, loading, transportation, etc., the deviation from the plane of the sediment (and corona) electrodes is (0.12 5 0.15390 (a) from the height (characteristic size) electrodes. M

Thus, in modern industrial electrofilters, in which the height of the electrode system is 77 16bm, the absolute value of the decentration (deviation from the vertical plane) of the sedimentary (and coronal) electrodes is (125 24)mm. Proportionally to the relative value of the decentration c I-AIP/Y, where Ai is the absolute value of the decentration, and is the distance between the “sedimentary and coronal electrodes in the lumen) the operating voltage O in the electrofilter decreases by the value u c Am: with SHI and (La " and, accordingly, the efficiency of the electrostatic precipitator decreases. The decrease in the efficiency of operation is also increased by a simultaneous (and quite significant) decrease in the corona discharge current | in the interelectrode gap of the electrostatic precipitator, in accordance with the voltage-current characteristic of the corona discharge. - In order to reduce the influence of the decentering of the Ai electrodes on the operation of the precipitator now, almost all over the world, they have switched to increasing the interelectrode gaps and, thereby, reducing the value of 5, since

Ap, as was mentioned above, does not depend on y and is a fixed value at a given length/height of the electrodes. o On the other hand, increasing the interelectrode distance (gap) leads (with unchanged dimensions of 50 electrostatic precipitators) to a proportional decrease in the total deposition surface of the electrostatic precipitators, which also adversely affects the efficiency of the precipitators. sl In connection with this, world practice has come to the optimal option, in which the inter-electrode distance is increased by 1.3 - 1.8 times, compared to the previously accepted one, which, as a final result, ensures sufficient efficiency of the work of electrofilters according to simultaneous reduction of their metal density and cost.

The known developments of electrostatic precipitators and electrode systems do not allow reducing the absolute value of Ai in the decentering of the electrode system and, thereby, increasing the efficiency of the electrostatic precipitators.

Thus, the disadvantages of known industrial electrostatic precipitators with electrodes of increased height (7 - 15 m and more) are ineffective cleaning of the upper part of the sediment electrodes from a layer of trapped dust (and, accordingly, a decrease in the efficiency of the electrostatic precipitator) and the short life of the elements of the shaking units (hammers, axles, 60 anvil, bolted connections, etc.), as well as a decrease in cleaning efficiency due to a decrease in the average value of the operating voltage (and corona discharge current) due to an increase in the value of the decentering of the electrode system.

Inefficient removal of a layer of dust from the upper part (up to 3095 surface) of sediment electrodes and, related to this, a decrease in the efficiency of electrostatic precipitators is well-known, especially when cleaning gases from high-resistance dust, for example, in thermal power engineering, which is due to losses along the height of the electrode of impact energy hammer on the anvil located on the shaking beam at the lower end of the sediment electrode.

Increasing the impact energy (during shaking) by increasing the mass of the hammer destroys the electrode elements and sharply reduces the durability of the shaking assembly and sediment electrode elements, and therefore is practically not used.

In addition, the issue of reducing the decentering of the corona electrodes and increasing the efficiency of their cleaning from a layer of dust is not resolved in the known electrostatic precipitator.

An electrofilter is also known (Y.A. Popov, S.S. Yankovsky and others. Gas cleaning equipment: Catalog, M.,

TsintikhyImneftemash, 1981. p.5-7), in which the coronal electrodes are tapped in two levels. This solution improves the removal of the dust layer from the corona electrodes, but this is not enough, considering the significant loss of 7/o impact energy in the support frames due to the rigid connection of the corona electrodes with the support frames.

Such an electrofilter does not solve the problem of reducing the decentering of electrode systems in an economically feasible way, as well as improving the cleaning of the dust layer of the upper part of the sediment electrodes, which is farthest from the shaking beam.

The closest to the claimed invention in terms of technical essence and achievable result is the 75 electrostatic precipitator (Patent of Ukraine Mo13398, IPC? VOoZS3/08, publ. 28.02.1997, bulletin Mo11, according to which the sedimentary electrode of the electrostatic precipitator is collected from sedimentary elements made in the form of serially connected plates, each of which is perpendicular to the previous one, while the end plates are made of the same length, and the plate elements in a row are installed with a gap of 5 between them to form through channels for the passage of gas, and the ratio of the width of 5 gaps in the placement plane of the end plates of adjacent lamellar elements and the length of the end plate is 0.25-0.50, and the ratio of channel width a e between the initial and final end plates along the gas flow of adjacent lamellar elements in a row and width 2 is 0.75--1.5 .

The disadvantages of this electrostatic precipitator are also the lack of a solution to the problem of reducing the amount of decentering of electrode systems and intensifying the process of cleaning the surface of sedimentary and coronal electrodes from a layer of dust, the tendency to the formation of hard-to-shake deposits of some types of dust on the "elements of the sedimentary electrode in the places where the plates are joined at right angles, and also the need to maintain the ratio of the gap 5 and the interelectrode gap y: 8 2 0.3 to prevent the occurrence of electrical breakdown of gas on the edges of the elements that form the gaps 5, which is caused by the right angle between the end and middle plates of the sediment element. i am

The invention is based on the task of creating a new structure of the electrostatic precipitator, which will allow increasing the efficiency of the electrostatic precipitator both by reducing the decentration of the deposition and coronal electrodes by almost half, provided that the total deposition surface area is preserved and increased, and also by av) due to the intensification of the gas purification process by using aerodynamic forces of the gas flow. In addition, the claimed invention provides a more effective removal of the layer of trapped dust from the surface of the sediment electrodes, especially from their upper part, which ensures an increase in the efficiency of gas purification in the electrostatic precipitator, and, accordingly, increases the efficiency of the electrostatic precipitator as a whole and, at the same time , increases the service life of the electrostatic precipitator. The new design also provides an increase in the value of the current and voltage of the corona discharge in the inter-electrode gap due to more effective shaking of dust from the З7З 70 corona electrodes, which contributes to increasing the efficiency of the electrofilter, allows to prevent excessive values of out-of-planeness and propeller of the corona and sediment electrodes, simplifies and "c makes assembly and installation of the electrofilter cheaper.

The task is solved by the fact that in a well-known electrostatic precipitator, which includes a housing, inlet and outlet nozzles and sediment electrodes installed between them parallel to the gas flow, collected from 35 plate sediment elements fixed in the upper and lower beams of the sediment electrode, located between them corona electrodes installed on support frames that are suspended on insulators, fixed on o anvil electrodes, hammer mechanisms for shaking electrodes that interact with anvils, fasteners and o limiters, according to the invention, sediment electrodes are made in height sectional, with the ratio of the sizes of the sections si 70 Nino-1:2-211, sl de N; - the height of the upper section,

H" is the height of the lower section, the ends of the adjacent sections of the sediment electrodes are equipped with horizontal slats fixed on plate sediment elements, while the slats of the adjacent sections in height are connected to each other and form an additional middle beam for shaking the sediment electrode, which is equipped at both ends with additional . latches that interact with the additional limiters of the transverse movement of the sediment electrode in its middle height part installed on the body, and the anvil installed on one of the ends of the middle shaking beam, the corona electrodes are made of sections, each section is freely installed on support frames and equipped with connected to the support frames by fasteners, while the smallest distance a In the clearance between the shaking beam of the sediment electrode and the ends of the sections of adjacent corona electrodes and the distance p in the clearance between the sediment and corona electrodes are selected from the ratio un, the sediment electrode is made gas-permeable and consists of lamellar sediment elements, where Installed consecutively in one plane with a pitch of z and fixed between two beams of the sediment electrode, and the lamellar sediment elements of the sediment electrode are made in the form of a profile, the cross section of which has the appearance of a broken line of a 2-shaped form, consisting of three consecutive o connected segments a, b, c, while the extreme segments a and c have the same length, are parallel to each other and are located in parallel planes, separated from each other by a distance where, the middle segment 5 of the broken line connects both extreme Segments and its length is 0.25a 56 51.58, the internal angle 2 between the middle segment b and segments a and c is 1502, the size of the interelectrode gap P and the distance d correspond to the ratio a, the walking step z is 5 5 2 crore VO - DI.

Due to the implementation of sedimentary electrodes in height sectional with the ratio of their vertical dimensions

N:ng-1:2-2:1 and taking into account that the ends of the adjacent sections of the sediment electrodes are equipped with horizontal slats fixed on plate sediment elements, and the slats of the adjacent sections in height are connected to each other and form an additional middle beam of the sediment electrode, it is ensured significant reduction (doubled or almost doubled) of the decentering of the sediment electrodes, provided that the total surface area of the deposition with 7-like sediment elements is preserved or increased.

Equipping the additional middle beam of the sediment electrode at both ends with additional fasteners that limit the transverse movement of the sediment electrode in its middle height by interacting with additional limiters installed on the body of the electrofilter or its elements, provides additional fixation of the position of the sediment electrode relative to the coronal one in its middle, the most dangerous" from the point of view of the largest value of decentration Ai , part and, thereby, makes it possible to achieve "the highest voltage and current of the corona discharge in the interelectrode gap, which ensures an increase in the efficiency of gas purification in the electrofilter.

The shaking beam is formed due to the equipment of the additional middle beam of the sedimentary electrode with an anvil installed at one of its ends, which makes it possible to more effectively remove the layer of trapped dust from the IF) of the entire surface of the sedimentary electrodes, including their upper parts, at the expense of a significant, almost doubled , reducing their distance from the shaking beam and, accordingly, ensures an increase in the efficiency of the electrostatic precipitator as a whole and, at the same time, increases the service life of the electrostatic precipitator due to a partial reduction (ав) of the mass of the hammers and a reduction in the operating time of the mechanisms for removing trapped dust. at

Making the corona electrodes sectional so that each section is freely installed on the support frames with two supports and is equipped with transverse movement clamps connected to the support frames and an anvil. It is ensured by a more effective shaking of the dust layer from the corona electrodes due to a more effective use of the impact energy caused by the reduction loss of impact energy in nodes of free support of coronal electrodes on the support frames, on the one hand, and due to the concentration of impact energy in the “significantly reduced, almost halved, coronal electrode, on the other hand, which, thereby, contributes to an increase in average voltage and current corona discharge and, thus, ensures an increase in the efficiency of the work of the electrostatic precipitator as a whole. h Due to the fact that the distance 4 in the clearance between the additional average shaking beam of the sedimentary -» electrode and the ends of the sections of adjacent corona electrodes and the distance n in the clearance between the corona and sediment electrodes is gi: LV, the maximum value of the current and voltage of the corona discharge in the interelectrode is ensured the gap of the electrostatic precipitator, necessary to achieve the highest efficiency - the operation of the electrostatic precipitator. In addition, it makes it possible to prevent an electrical breakdown of the gas in the interelectrode space between the adjacent ends of the corona electrode sections, on the one hand, and the additional middle beam of shaking of the sediment electrodes, on the other hand. o Due to the fact that the lamellar sedimentary elements of the sedimentary electrode are installed sequentially in one s 20 plane with a pitch of 5, fixed between two beams of the sedimentary electrode and made in the form of a profile, the cross-section of which has the appearance of a broken line of a 2-shaped form, consisting of three consecutively connected lines of segments a, b, c, while the extreme segments a and c have the same length, are parallel to each other and are located in parallel planes, separated from each other by a distance where, the middle segment b of the broken line connects both extreme segments a and c, and its length is 5o P.25a x 1.5a, the internal angle 2 between the middle segment b and segments a and c is 1502, the size of the interelectrode gap Pp and the distance d correspond to the ratio 6o Z. On, and step z is a krSovY VO - DIx 5 5 2 krsOY VO - DIh, optimal conditions are created for the flow of a stable and developed corona discharge in the interelectrode gap of the electrofilter under conditions of plane-parallel e of the electric field without the occurrence of an edge effect, b5 provides gas permeability and a developed deposition surface of the deposition electrodes, which contributes to increasing the efficiency of the electrostatic precipitator both due to the intensification of the process of charging and deposition of dust particles, and due to the penetration of gas with electrically charged particles to the surface of the deposition electrodes due to turbulent pulsations of the gas flow and gas flows between the channels of the electrofilter through gas-permeable sediment electrodes.

Flows of purified gas between adjacent channels through gas-permeable sediment electrodes occur both due to turbulent pulsations of the gas flow when gas flows through the gas channels of the electrostatic precipitator, and due to the combined movement of gas in the electrostatic precipitator (along and through gas-permeable sediment electrodes) with the help of plugs that installed at the entrance and exit of gas channels. 70 The essence of the claimed invention is explained by the drawings, which show: - Fig. 1 - electrofilter, general view, - Fig. 2 - output A - A, - Fig. 3 - cross section of a 2-shaped element of a sediment electrode, - Fig. 4 - type B - B.

The electrostatic precipitator consists of body 1, inlet 2 and outlet Z nozzles and sediment electrodes 4 installed between them parallel to the gas flow, collected from lamellar sediment elements 5, fixed in the upper b and lower 7 beams of the sediment electrode 4, corona electrodes 8 located between them, which are installed on the support frames 9, which are suspended on the insulators 10, installed on the body 1 of the electrofilter, fixed on the electrodes 4 and 8, anvils, respectively, 11 and 12, hammer shaking mechanisms, respectively, 13 and 14, which interact with the anvils 11, 12 , retainers 15 and limiters 16.

Sediment electrodes 4 are sectional in height, with the ratio of the sizes of the sections H./:No-1:2-2:1 (No - the height of the upper section, No - the height of the lower section). The ends of the adjacent sections of the sediment electrodes 4 are equipped with bars 17 fixed on the plate sediment elements 5, while the bars of the adjacent sections in height are connected to each other and form an additional middle shaking beam 18 of the sediment electrode 4, which is equipped at both ends with additional fasteners 19, which interact with the additional limiters 20 installed on the body 1 of the transverse movement of the sediment electrode 4 in its middle height part, and the anvil 11 installed on one of the ends of the middle shaking beam 18.

Corona electrodes 8 are made of sections, each section is freely installed on support frames 9 and equipped with fasteners 15 connected to support frames 9, while the smallest distance and in the clearance between (0 shaking beam 18 of sediment electrode 4 and the ends of sections of adjacent corona electrodes 8 and the distance and in the clearance between the sedimentary 4 and coronal 8 electrodes is selected from the ratio of Хн, o the plate sedimentary elements 5 of the sedimentary electrode 4 are installed in series in the same plane with the step 8, and are fixed between two beams of the sedimentary electrode 4 and are made in the form of a profile, the cross section of which has the form of a broken line of a 2-shaped form, consisting of three successively connected segments a, b, c, and o

The extreme segments a and c have the same length, are parallel to each other and are located in parallel planes, separated from each other by a distance av, the middle segment B of the broken line connects both extreme segments a and c, and its length is 0.258 5 B 5 1.58, the internal angle Dd between the middle segment b and segments a and c is 902 5 8 54502, the value of the inter-electrode gap p and the distance d correspond to the ratio "lyu Z"04n, and the step z is i krsoI 802 - 0)ххх 5 2 kvsozYvO g - DI. With c Electrofilter works as follows. y Contaminated gas enters the electrofilter for cleaning through the inlet pipe 2 and is directed into the "" channels formed by sediment electrodes 4 with corona electrodes 8 installed in these channels.

Dust particles in the polluted gas stream, due to the corona discharge that occurs in the interelectrode gap when a high voltage is applied to the electrodes 8 relative to the electrodes 4, receive -I electric charge.

In the further interaction of the electric charge of the dust particles with the electric field of the corona discharge, the dust particles move to the deposition electrodes 4 and are deposited on them. o Due to the gas permeability of sediment electrodes 4, which are collected from lamellar sediment elements 5, 5p installed with a step z and made in the form of a profile, the cross section of which has the appearance of a broken line and 2-shaped form, the penetration of gas with electrically charged dust particles is ensured to the surface 4 of the sediment electrodes 4 under the influence of turbulent pulsations of the gas flow and gas flows between the channels of the electrofilter through the sediment electrodes 4, which contributes to the intensification of the process of trapping dust particles.

Some of the dust deposited on the corona electrodes 8 is shaken off them with the help of the Hammer shaking mechanism 14 and the anvil 12.

After the accumulation of dust on the sediment electrodes 4 include hammer shaking mechanisms 13, which

P" interact with the anvils 11 by impact, which leads to vibrations in the sediment electrodes 4, under the action of which the captured dust is shaken into the hopper 21.

The dust-free gas is discharged from the electrostatic precipitator through outlet pipe 3. 60 b5 g ra 4 E K ! and : -; г я и Ц ств -ы (и т, потих х их 5 щ 70 B | ТИМ і І І ; І І ш гі і ві. - і " or ny ih - sho A і . still U shiya

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Claims (1)

The formula of the invention Electrofilter containing a housing, inlet and outlet nozzles and installed between them in parallel with the gas flow (3 sedimentary electrodes, collected from lamellar sedimentary elements fixed in the upper and lower beams of the sedimentary electrode, corona electrodes located between them, installed on supporting frames, which are suspended on insulators, fixed on the anvil electrodes, hammer mechanisms for shaking the electrodes, which o interact with the anvils, fasteners and limiters, which is distinguished by the fact that the sediment electrodes are sectional in height with the ratio of the sizes of the sections o Nitny" - 1:2 -2:1, che de H; - the height of the upper section, H" - the height of the lower section, the ends of the adjacent sections of the sediment electrodes are equipped with horizontal bars fixed on the plate sediment elements, while the bars of the adjacent sections in height are connected to each other and 470 form an additional middle beam for shaking the sediment electrode, which is equipped at both ends with additional - with latches, which interact with the additional limiters of the transverse movement "from the sediment electrode to its middle height part, and the anvil installed on one of the ends of the middle" shaking beam installed on the body, the corona electrodes are made of sections, each section is freely installed on support frames and equipped connected to the support frames by fasteners, while the smallest distance a in the clearance between the shaking beam of the sediment electrode and the ends of the sections of the adjacent corona electrodes and the distance y - and the clearance between the sediment and corona electrodes are selected from the ratio o Х, the sediment electrode is made of gas permeable and consists of from lamellar sedimentary elements, installed in series in the same plane with step 5 and fixed between two beams of the sedimentary electrode, sl 20, and the lamellar sedimentary elements of the sedimentary electrode are made in the form of a profile, the cross section of which has the appearance of a broken line of a 2-shaped form, consisting of with three consecutively connected segments a, b, c, and the extreme segments a and c have the same length, are parallel to each other and are located in parallel planes, separated from each other by a distance where, the middle segment 5 of the broken line connects both extreme segments a and c, and its length is 0d, 2za5x15a, P» the internal angle y between the middle segment B and segments a and c is called 1507, the value of the interelectrode gap P and the distance d correspond to the ratio 4. со4 а срок з is а BSov(1802-63 х вх Да квСов(180 2-31. b5 мия " ; " " ; ; шо Official Bulletin "Industrial Property". Book 1 "Inventions, useful models, topographies of integrated microcircuits ", 2004, M 9, 15.09.2004. The State Department of Intellectual Property of the Ministry of Education and Science of Ukraine. "IS) and "c) "c) m. shi s ;" -I («c) («c) c 50 sl 60 b5