RU2169621C1 - Electric filter of polymer material - Google Patents

Abstract

FIELD: manufacture and operation of gas cleaning and dust trapping apparatuses used in chemical, petrochemical industries, non-ferrous metallurgy, production of fertilizers and other spheres. SUBSTANCE: electric filter of polymer material is made of body, system of precipitation electrodes in the form of module plates, system of corona-forming electrodes with supporting and corona displaying parts, system of suspension of plates of precipitation electrodes and system of fixation of precipitation and corona-forming electrodes. Module plates of system of precipitation electrodes and corona displaying parts of system of corona-forming electrodes are produced from polymer material with heat conduction factor greater than 0.6 and less than 0.8 W/(m K). EFFECT: prolonged service life of electric filter. 6 cl, 3 dwg

Description

 The invention relates to techniques for the manufacture and operation of gas cleaning and dust collecting devices and can be used in the chemical and petrochemical industries, in non-ferrous metallurgy, in the production of mineral fertilizers, and others.

 The closest to the proposed device is an electrostatic precipitator made of polymer material, which contains a housing, a system of precipitation electrodes in the form of modular plates, a system of corona electrodes with corona and bearing parts, a suspension system of plates of precipitation electrodes and a system for fixing the precipitation and corona electrodes. The modular plates of the precipitation electrodes and the corona parts of the corona electrodes are made of a polymer material with a thermal conductivity of 0.3 - 0.6 W / (m • K). Modular plates are installed with a gap and have the shape of a hexagon. The corona part of the corona electrodes is made of separate elements with teeth, and the bearing part is made of metal wire with a rectangular sheath (RU, patent N 2151009, B.I. N 17, 2000).

 This electrostatic precipitator has a low service life. This is due to the fact that during operation the resistance of the polymer material used in the electrostatic precipitator is insufficient and it is destroyed under the influence of powerful thermal energy generated at the time of electrical breakdown, leading to an increase in the temperature of the polymer material at the breakdown location.

 The objective of the invention is the provision of reliable purification of chemically aggressive gases.

 The solution to the problem is achieved by the technical result, which ensures an increase in the service life of the electrostatic precipitator by eliminating the destruction of structural polymer material during electrical breakdowns of the interelectrode gap.

 The technical result is achieved using the proposed electrostatic precipitator made of a polymeric material containing a housing, a system of precipitation electrodes in the form of modular plates, a system of corona electrodes with bearing and corona parts, a suspension system of plates of precipitation electrodes and a system for fixing the precipitation and corona electrodes, the distinctive features of which include that the modular plates of the precipitation electrode system and the corona parts of the corona electrode system are made of polymer material with a thermal conductivity coefficient of greater than 0.6 and less than 0.8 W / (m • K).

 Moreover, the corona part of the corona electrodes is made of polymer tubes equipped with polymer gear ribs located on the outer surface of the tubes.

In addition, when performing the proposed electrostatic precipitator with flat deposition electrodes, the polymer tubes of the corona electrodes have 2 to 4 polymer gear ribs. With four polymer gear ribs on the outer surface of the polymer tubes of the corona electrodes, the ribs are directed in pairs towards flat deposition electrodes with an angle of 60 - 90 ^o between the ribs of one pair, an angle of 90 - 120 ^o between adjacent ribs of different pairs. When precipitation electrodes in the form of a hexagon, each polymer gear rib is directed to the corresponding side of the hexagon, the ribs are located at an angle of 60 - 90 ^o between them. The angle of the polymer tooth edges of the corona electrodes and their number is optimal, a decrease in the angle leads to the effect of "screening" and, accordingly, a decrease in the current of the corona discharge, and an increase in the angle leads to the effect of a "slip" when some of the particles polluting the gas without receiving an electric charge are removed together with the gas stream from the electrostatic precipitator.

 Also, the supporting part of the corona electrodes is made of metal or a polymeric material.

 In FIG. 1 shows an electrostatic precipitator made of polymer material, general view.

 In FIG. 2 shows a section AA of the flat electrode and the corona electrode in FIG. 1.

 In FIG. 3 shows a section BB of the precipitation electrodes in the form of a hexagon (honeycomb precipitation system) and the corona electrode in FIG. 1.

An electrostatic precipitator made of polymer material consists of a housing 1, a system of precipitation electrodes 2 in the form of modular plates 3, a system of corona electrodes 4 with a carrier 5 and a corona part 6 in the form of polymer tubes 7 with polymer gear ribs 8, which are located on the outer surface of the tubes 7 and precipitation electrodes 2 - flat (Fig. 2) have a quantity of 2 - 4, with four polymer serrated ribs the latter are directed in pairs towards the sides of the flat precipitation electrodes with an angle of 60 - 90 ^o between the ribs 8 of one pair, an angle of 90 - 120 ^o between s settling ribs 8 of different pairs, when the precipitation electrodes 2 are in the form of a hexagon (Fig. 3), each of the ribs 8 is directed to the corresponding side of the hexagon, the ribs 8 are located at an angle of 60 - 90 ^o between them, the suspension system with a tube sheet 9 for modular suspension plates 3 of precipitation electrodes 2, fixing systems 10 of precipitation 2 and corona 4 electrodes. The modular plates 3 and the corona parts 6, 7 and 8 of the corona electrodes 4 are made of a polymer material with a thermal conductivity greater than 0.6 and less than 0.8 W / (m • K), and the supporting part 5 of the corona electrodes 4 is made of metal or polymer material. In the housing 1 there are nozzles 11 and 12 for the entry of the contaminated and the outlet of the purified gas, respectively.

 An electrostatic precipitator made of polymer material works as follows.

 The contaminated chemically aggressive gas enters through the nozzle 11 into the electrostatic precipitator, passes through the gas distribution system, after which the gas is evenly distributed over the cross-section of the electrostatic precipitator, and enters its core, consisting of 4 corona and 2 precipitation electrodes. Particles polluting the gas, falling under the influence of a corona discharge, are charged and move towards the precipitating 2 electrodes on which they settle, and then are removed through the nozzle 12 by one of the known methods.

 During operation of the electrostatic precipitator, a chemically aggressive gas entering the active zone of the electrostatic precipitator - the interelectrode gap, falls under the action of spark electric breakdowns arising in it, accompanied by the release of powerful thermal energy. This leads to an increase in the temperature of the polymeric material at the breakdown site, its melting, the beginning of destruction and subsequent destruction. The proposed technical solution provides dispersion in the volume of the polymer material and the removal of thermal energy during electrical breakdowns. With the selected coefficient of thermal conductivity of the polymeric material, the surface temperature of the electrodes is the value of the guaranteed operability of the polymeric material. The material is not destroyed. As a result, the service life of the electrostatic precipitator increases.

 The data of the dependence of the coefficient of thermal conductivity of the polymer material and the temperature of the polymer material at the place of electrical breakdown of the interelectrode gap during operation of the proposed electrostatic precipitator and prototype are presented in the table.

As can be seen from the table, when the coefficient of thermal conductivity is greater than 0.6 and less and 0.8 W / (m • K), the temperature of the polymer material at the point of electrical breakdown is more than 90 ^o C and less than 120 ^o C, which guarantees the operation of the polymer material in working condition. A further increase in the coefficient of thermal conductivity of the polymer material leads to a slight decrease in the temperature of the polymer material at the place of electrical breakdown and at the same time there is a significant embrittlement of the polymer material. That is, a polymer material with a thermal conductivity coefficient of greater than 0.6 and less than 0.8 W / (m • K) is optimal for use. With this value of the coefficient of thermal conductivity of the polymer material, the overhaul guaranteed service life of the internal polymer equipment of wet acid electrostatic precipitators is 5 years, while the prototype is 3.5 to 4 years.

 Thus, the service life of the proposed electrostatic precipitator made of polymeric material is increased by 1.25 - 1.4 times compared with the prototype, and the full service life is at least 12 years.

Claims (7)

 1. An electrostatic precipitator made of a polymeric material, comprising a housing, a system of precipitation electrodes in the form of modular polymer plates, a system of corona electrodes with a bearing and corona parts, a suspension system of plates of the precipitation electrodes and a system for fixing the precipitation and corona electrodes, characterized in that the modular plates of the precipitation electrode system and the corona parts of the corona electrode system are made of a polymer material with a thermal conductivity greater than 0.6 and less than 0.8 W / (m • K).  2. The electrostatic precipitator according to claim 1, characterized in that the corona part of the corona electrodes is made of polymer tubes equipped with polymer gear ribs located on the outer surface of the tubes.  3. The electrostatic precipitator according to claim 1 or 2, characterized in that in it, with flat deposition electrodes, the polymer tubes of the corona electrodes have 2 to 4 polymer gear ribs. 4. The electrostatic precipitator according to claim 1, or 2, or 3, characterized in that the four polymer toothed ribs of the polymer tubes of the corona electrodes are directed in pairs to the sides of flat deposition electrodes with an angle of 60 - 90 ^o between the ribs of one pair, an angle of 90 - 120 ^o between adjacent ribs of different pairs.  5. The electrostatic precipitator according to claim 1 or 2, characterized in that in it, when the precipitation electrodes are in the form of a hexagon, each polymer gear rib of the polymer tubes of the corona electrodes is directed to the corresponding side of the hexagon. 6. The electrostatic precipitator according to claim 1, or 2, or 5, characterized in that the polymer tubes of the corona electrodes of the electrostatic precipitating electrodes with hexagonal electrodes have ribs located at an angle of 60 - 90 ^o relative to each other.  7. The electrostatic precipitator according to claim 1, characterized in that the supporting part of the corona electrodes is made of metal or a polymeric material.

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