RU2806048C1 - Electric filter - Google Patents

Abstract

FIELD: gas purification.

SUBSTANCE: invention relates to the purification of gases from dust and microorganisms. The electrostatic precipitator includes a cylindrical housing with a swirler, gas inlet pipes, dust concentrate outlet pipes, corona and precipitation electrodes, a hopper and a high-voltage power supply. The body is made vertical with a lower conical part. The swirler is made in the form of an even number of electrically conductive blades-plates installed inside the housing in its upper part parallel to the axis and oriented in spiral directions. The blade-plates are electrodes - the corona surfaces are the sharpened edges of the plates facing the central axis of the spiral - the axis of the body. Gas inlet pipes are placed between the electrode plates and cut tangentially into the housing; the electrodes are connected to the poles of the power supply in pairs-parallel and installed in the housing with the ability to move in the radial direction and fix their position individually.

EFFECT: increased efficiency of gas purification and reliability of the device.

2 cl, 3 dwg

Description

The invention relates to the sanitary purification of air from dust and microorganisms, the purification of process and ventilation gases and can be used in the energy sector, in medical institutions, as well as in other sectors of the national economy where it is necessary to purify gases from dust.

A known installation for purifying gases from dust (see US patent No. 4072477, M. class B03C 3/01, 1978), including a housing, a system of charging electrodes for purified gas, a system of charging electrodes for filter material, a cyclone for separating heavy particles and bag filter for cleaning from small dust fractions. Dust separation in the installation is carried out due to the fact that floating charged particles of filter material and dust, charged in opposite ways, are attracted to each other by electrostatic forces.

The disadvantage of this installation is that the gas flow must be cleaned in a cyclone, where coarse dust is captured, and then in a bag filter to remove small dust fractions, while dust particles coagulated on the particles of the filter material can be separated from the latter due to the insignificant adhesion force .

An inertial-electrostatic dust concentrator is also known (A.S. USSR No. 559726, M. class B03S 3/14, Inertial-electrostatic dust concentrator / Yu.A. Dolbnya, M.Ya. Protsaylo. Application. 03.12.1975; Publ. 30.05 .1977, Bulletin No. 20), including a housing with a swirler located in it with dividers, blades and pipes for inlet of the purified gas, outlet of the purified gas and outlet of the concentrate, and the housing is equipped with additional blades located between the blades of the swirler. The swirler is connected to one of the poles of the high-voltage current source and is a discharge electrode, and the body with blades is connected to the other and is a collecting electrode. In addition, the additional blades are made in the form of a wedge, and the gap between the top of the wedge and the swirl dividers is equal to the interelectrode distance.

The purified gas, passing through the channels between the blades, swirls, and large dust particles, due to inertial forces, are thrown towards the walls of the housing, at the same time all dust particles pass through the channels between the electrode blades, are charged in the electric field of the corona discharge and, under the influence of electrostatic force, also rush towards body. The use of the described device makes it possible to increase the efficiency of gas purification when operating as an upstream stage in front of an electric precipitator, but requires the installation of an additional blower fan to create the required gas flow rate and greater labor costs for cleaning the collecting electrodes.

An electric precipitator for purifying gases from dust is also known (RF Patent No. 163132 M. class B03S 3/14. Electric precipitator / Porsev E.G., Konovalenko A.I. - Inventions and utility models of the Russian Federation: application 12/09/2015 publ. 10.07 .2016, Bull. 19), which is a prototype of the claimed technical solution, containing a cylindrical body with a swirler, pipes for gas inlet and outlet, pipes for inlet and outlet of dust concentrate, corona and precipitation electrodes, a hopper and a high-voltage power source, and the body is made vertical with a lower conical part, the swirler is made in the form of an even number of electrically conductive blades-plates installed inside the housing in its upper part parallel to the axis and oriented in spiral directions, and the blades-plates are electrodes - the corona surfaces are the sharpened ribs of the blades-plates facing the central the spiral axes are the body axes, gas inlet pipes are placed between the blades-plates of the electrodes and cut tangentially into the body, the electrodes are connected to the poles of the power source in pairs and parallel. In addition, an outlet pipe for dust is located coaxially with the housing in its conical part, connected to the hopper, and in the upper part of the body there is an outlet pipe for purified gas, and the outlet pipe is lowered into the housing to the level where the conical part of the body meets the cylindrical one.

An electric precipitator allows for deep cleaning of dust-laden gas from large and small dust particles, but due to the fact that the intensity of the corona discharge on the corona electrodes is different with different polarities of the electrodes, the flows of charged air through adjacent gaps-cavities will not be consistent in speed, and the cleaning efficiency will decrease.

In addition, due to the lack of speed matching, turbulent gas flow and deterioration of the adhesion of positively and negatively charged particles are possible, which will reduce the reliability of the electrostatic precipitator.

The objective of the present invention is to increase the efficiency of gas purification from dust particles and increase the reliability of the electrostatic precipitator.

The use of the proposed design will improve the efficiency of gas purification from dust particles, spores of pathogenic fungi and viruses, as well as increase the reliability of the operation of electrostatic precipitators-cyclones due to the fact that the electrode plates are installed in the housing with the ability to move in the radial direction relative to the cylindrical housing and fix their position individually, such as locking screws. The specified design is new in the declared set of features.

The implementation of corona electrode plates with the ability to move in the radial direction relative to the cylindrical body and fix their position individually, for example with locking screws, is unknown from the prior art, that is, the presented design is new in the claimed set of features.

The dependence of the speed of the “ionic wind” on the electric field strength and the corona discharge electric current density is known in science and technology [1], and it is also known that the corona discharge current density depends on the polarity of the corona electrode [2]. For this reason, when multi-polar corona discharges operate in one volume, flows of charged air (gas) inconsistent in speed appear inside the cyclone-electric precipitator, which cause turbulent gas flow and, as a consequence, deterioration in the adhesion of charged particles, a decrease in the efficiency of gas purification from dust and a decrease in reliability operation of the electrostatic precipitator.

The implementation of an electrostatic precipitator with flat pointed electrodes is known in the art, but in this totality, the listed characteristics exhibit new qualities, namely:

a) in equalizing the velocities of gas movement in different-polar areas of corona discharges, which gives a turbulent flow of gases at the exit of the discharge areas and, accordingly, more complete neutralization of stuck together enlarged dust particles;

b) the possibility of regulating and adjusting the electric field strength in each discharge cavity in order to individually adjust the flow of charged particles, respectively, and increase the reliability of the electrostatic precipitator.

Thus, the technical result expected from the use of the invention is to increase the efficiency of gas purification from suspended particles and increase the reliability of the electrostatic precipitator.

This result is achieved by the fact that the claimed technical solution has properties that are not equal to the sum of the known properties:

a) increasing the efficiency of gas purification is achieved by turbulent mixing of oppositely charged gas flows and, as a consequence, more effective adhesion of oppositely charged dust particles;

b) increasing the reliability of the electrostatic precipitator is achieved by the ability to precisely adjust the speeds of the “ionic wind” in different-polarity discharge areas.

In fig. Figure 1 shows the empirical dependence of the speed of the “ionic wind” on the electric field strength.

In fig. Figure 2 shows the empirical dependence of the corona discharge current density on the strength and polarity of the electric field.

In fig. Figure 3 shows a diagram for setting the electric field strength in the discharge gaps of the electrostatic precipitator.

The electrostatic precipitator (Fig. 3) includes a cylindrical housing 1 with a swirler, gas inlet pipes 2, a dust outlet pipe 3, corona electrodes 4, collecting electrodes 5, a hopper and a high-voltage power source 6, and the housing 1 is made vertical with a lower conical part, The swirler is made in the form of an even number of electrically conductive blades-plates 5, installed inside the housing 1 in its upper part parallel to the axis and oriented in spiral directions, and the blades-plates are electrodes - the corona surfaces are the sharpened ribs of 4 blades-plates facing the central axis of the spiral – the axes of the housing 1, gas inlet pipes 2 are placed between the blades-plates of the electrodes and tangentially embedded into the housing 1, the electrodes 5 are connected to the poles of the power source 6 in pairs-parallel, and the electrodes 5 are installed in the housing 1 with the ability to move in the radial direction and fix their positions are individual, for example with locking screws 7.

The electrostatic precipitator works as follows. The power source 6 is turned on, while a high electrical voltage is supplied to the electrodes 4, 5 through the wires and corona discharges appear in the gaps between the corona 4 and precipitation 5 electrodes, which give rise to “ionic wind”. Due to the fact that the blade-plates of the electrodes are located in spiral directions, the flows of charged gas in various discharge gaps are forced closer to the axis of the cylindrical part of the housing 1, add up and form annular air flows. Then, through gas inlet pipes 2, dusty gas is fed into the discharge gaps, while dust particles, spores of pathogenic fungi and viruses are charged in each gap with an electric charge of their sign (“+” or “–”), and then entering the annular flow, they stick together , form larger particles and settle in the lower part of the cylinder, into the dust outlet pipe 3 and the dust bin, from where they are discharged outside. Due to the fact that the speed of gas movement depends on the electric field strength, the density of the electric current of the corona discharge (see Fig. 1, 2), as well as on the mass of the electric charge carriers (electron, or α-particle, or positive ion) speed the movements of the gas flow in the cavities between the electrode plates will be different and, accordingly, turbulization of the total gas flow is possible, worsening the characteristics of the electrostatic precipitator. The difference in the speed of gas flows is compensated by adjusting the electric field strength in the discharge gaps by changing the gaps between the corona 4 and precipitation 5 parts of the electrode plates, fixing these gaps using locking screws 7.

A specific embodiment of the device is an electric precipitator for disinfecting the atmosphere of medical institutions. The electrostatic precipitator body is made of SOL-10 plexiglass, the outer diameter of the cylindrical part is 300 mm, the height of the cylinder is 400 mm, the number of inlet pipes is 6, the air capacity is 300 m ³ /hour at a voltage at the electrodes of 35 kV.

The use of the proposed electrostatic precipitator will improve the efficiency of gas purification from dust, spores of pathogenic fungi and viruses due to the fact that turbulence of gas flows passing through the cavities of positive and negative charges is eliminated due to equalization of the speeds of the “ionic wind”, and will increase the reliability of the electrostatic precipitator due to the possibility of precise settings of the “ion wind” speed in multi-polar discharge cavities.

Claims (2)

1. An electric precipitator for purifying gases from dust, including a cylindrical body with a swirler, gas inlet pipes, dust concentrate outlet pipes, corona and precipitation electrodes, a hopper and a high-voltage power supply, the body is made vertical with a lower conical part, the swirler is made in the form an even number of electrically conductive blades-plates installed inside the housing in its upper part parallel to the axis and oriented along the spiral directions, and the blades-plates are electrodes - the corona surfaces are sharpened ribs of the plates facing the central axis of the spiral - the axis of the housing, gas inlet pipes are placed between the electrode plates and embedded tangentially into the housing, the electrodes are connected to the poles of the power supply in pairs-parallel, characterized in that the electrodes are installed in the housing with the ability to move in the radial direction and fix their position individually. 2. An electric precipitator for purifying gases from dust according to claim 1, characterized in that the electrodes are fixed with locking screws.