RU2612292C1 - Method for removing charged particles from gas flow - Google Patents

Abstract

FIELD: gas industry.

SUBSTANCE: invention relates to methods for cleaning gases and can be used in power engineering, in ferrous and nonferrous metallurgy, cement, nuclear and other industries. Removal of charged particles from gas flow is performed by electric field of electric filter. To grip microparticles, variable electric field of quadrupole type is used. Variable field generates linear electrodynamic trap, its axis is perpendicular to direction of gas flow rate. In the trap charged particles are captured without depositing on electrodes and removal of trapped particles from gas flow along the axis of the trap by gravity and/or additional constant electric field.

EFFECT: higher degree of purification of gas and simplification of system for collecting microparticles.

1 cl, 2 dwg

Description

The invention relates to the field of gas purification from charged dust particles and can be used in energy, ferrous and non-ferrous metallurgy, cement, nuclear and other industries.

Known methods of purification of a gaseous medium based on the effect of coagulation - enlargement of suspended particles contained in gases by agglomeration, i.e. compounds of several particles into a single complex.

So, there is a known method of gas purification [Uzhov V.N., Waldberg A.Yu. Preparation of industrial gases for cleaning. M .: Chemistry, 1975, p. 49-50], in which a gas stream with negatively charged particles with a low specific resistance (10 ² Ohm⋅m) is passed through precipitation electrodes, to which a constant positive electric potential is supplied. In a collision with the electrode, the particle quickly loses its charge and acquires a positive charge. If the magnitude of the repulsive force exceeds the force of molecular adhesion of the particle to the surface of the electrode, this particle is repelled and gets back into the gas stream. In a gas stream, the particle is exposed to ion bombardment and again acquires a negative charge. Thus, the particle again begins to move to the precipitating electrode. The motion of such particles is spasmodic, with a large number of collisions between oscillating particles, which leads to their coalescence. When gases are purified from suspended particles with a large electrical resistivity (2⋅10 ⁸ Ohm⋅m), the reverse corona appears: a process in which positive ions and positively charged dust particles are released from the surface of the precipitation electrodes, which did not have time to discharge on the precipitation electrodes. The positively charged particles move towards the negatively charged particles, resulting in their agglomeration.

Coagulated particles enter the cyclone, where they are removed from the stream.

A disadvantage of the described type of devices is the limitation on the particle resistivity: up to 10 ² Ohm⋅m and above 2⋅10 ⁸ Ohm⋅m, as well as the need to create installations of sufficient length to ensure adhesion of all particles.

There are other filtration methods based on the installation of corona discharge blocks in the gas path, where particles are charged and subsequently deposited on precipitation electrodes.

A known method of purification of gases from particles suspended in them in the electric field of the electrostatic precipitator by passing purified gases through the gas channels of the electrostatic precipitator formed by precipitation electrodes with corona electrodes installed between them. In this case, particles suspended in gases are electrically charged in a corona discharge field organized in the interelectrode space of the electrostatic precipitator between the precipitation and corona electrodes. Under the influence of electric field forces, charged particles move towards the precipitation electrodes. Trapped particles are forcibly removed from the precipitation electrodes into the hopper of the electrostatic precipitator, and the purified gases are removed from the electrostatic precipitator (Handbook on dust and ash collection / M.I. Birger, V.A. Waldberg, B.I. Myagkov et al .; Ed. A.A. Rusanova. - M., 1983. - S. 198, 199).

Closest to the claimed invention is a gas purification method adopted as a prototype based on the principle of electrostatic air purification [Patent RU 2544202 C1, B03C 3/40, application. 12/30/2013, publ. 03/10/2015]. With this method of purification of gases from particles suspended in them in the electric field of the electrostatic precipitator when passing the cleaned gases through the gas channels of the electrostatic precipitator formed by precipitation electrodes with corona electrodes installed between them, the purified gases are additionally injected from one gas channel of the electrostatic precipitator into another gas channel adjacent to it and back through the precipitation electrodes, which are made gas permeable, while the injection is carried out through the passage section of the gas permeable clusive electrodes is adjusted based on the ratio of the total flow area of holes on the projection surface of the gas permeable precipitation electrode to the area of its projection surface. As a result, due to the multiple flow of gas with the charged particles contained in it from one gas channel of the electrostatic precipitator to another gas channel adjacent to it and vice versa, the residence time of charged particles in the electric field in the immediate vicinity of the deposition surface of the precipitation electrodes increases significantly, which increases the likelihood of their contact with precipitation electrodes and, thus, provides an increase in the efficiency of gas purification in the electrostatic precipitator as a whole.

A common drawback of the above solutions based on the principle of electrostatic air purification is associated with the presence of turbulence in the air flow near the surface of the precipitation electrodes and the limited residence time of charged particles near the precipitation electrodes, with the possibility of secondary entrainment of charged particles from the precipitation electrodes by the passing stream of the gas being cleaned, as well as the need use of additional devices for cleaning precipitation electrodes and removing dust particles in the receiving hopper .

The proposed object is based on the technical task to create a method of gas purification in which, by introducing new actions and new parameters for their implementation, it will help to achieve a technical result consisting in increasing the efficiency of gas purification by volume capture of charged particles and further contactless removal of trapped particles from air flow.

According to the proposed technical solution, charged particles are captured and held in volume in an alternating electric field of a quadrupole type [V. Paul. Electromagnetic traps for charged and neutral particles. Physics-Uspekhi 1990. Volume 160. Issue. 12. P. 109-127] without deposition on the electrodes and are removed from the air stream of the electrostatic precipitator into the receiving hopper under the action of gravity and an additional constant electric field without turning off the air flow and the use of additional mechanical devices.

The technical result is achieved by the fact that with this method of removing charged particles from the gas stream by the electric field of the electrostatic precipitator to capture particles, an inhomogeneous alternating electric field of the quadrupole type is used, which forms a linear electrodynamic trap whose axis is perpendicular to the direction of the gas flow and in which the capture of charged particles occurs without deposition on electrodes and removal of charged particles from the gas stream along the axis of the trap under the action of gravity and / or additional itelnogo constant electric field without disconnecting the air flow and the use of additional mechanical devices.

The technical result is achieved by the fact that with this method of removing charged particles suspended in the gas stream from the volume of the linear electrodynamic trap Paul into the receiving hopper, gravity is used in the case of a vertically oriented axis of the linear electrodynamic trap, under which the particles are lowered and deposited in the receiving hopper. To accelerate the process of particle deposition, an additional vertically oriented constant electric field can be supplied to the receiving hopper. In the case of the horizontally oriented axis of the linear electrodynamic trap, for the deposition of particles into the receiving hopper, it is necessary to supply an additional horizontally oriented electric field directed so that the charged particles move in the direction of the receiving hopper and are deposited in it.

Thus, when a gas flow with suspended charged particles passes through a linear electrodynamic trap, charged particles are trapped in the volume of the Paul linear electrodynamic trap. Trapped particles are removed from the volume of the trap under the action of gravity and an additional electric field into the receiving hopper during the operation of the electrostatic precipitator.

A variant of the device for implementing the proposed method is shown in FIG. 1. The device includes an electrostatic precipitator housing 1 and a receiving hopper for collecting particles removed from the gas stream 2. Inside the housing along its central axis are two pairs of identical metal electrodes 3, 4 and 5, 6. Electrodes 3-6 are fixed at the corners of the square, whose center coincides with the central axis of the housing. The electrode 7 is installed inside the housing from the opposite end relative to the receiving hopper. The electrode 7 is not in contact with the electrodes 3-6. Pairs of electrodes 3, 4 and 5, 6 are connected to an AC voltage source through an electric circuit with the ability to phase shift by π; between pairs: alternating voltage Usin (ωt) is applied to electrodes 3, 4, voltage -Usin (ωt) is applied to electrodes 5, 6. A constant potential V of the same sign as the sign of the particle charge is supplied to the electrode 7. On the side surface of the electrostatic precipitator there are inlet 8 and outlet 9 ventilation pipes. The air stream 10 with charged particles 11 is supplied to the inlet ventilation pipe. A clean air stream 12 enters the outlet pipe 9. The electrode power supply devices of FIG. 1 are not shown.

The operation of the device by the proposed method is as follows: the air flow with charged suspended particles enters through the inlet ventilation pipe into the device perpendicular to the axis of the linear electrodynamic trap, consisting of electrodes 3-6. Charged particles along with the stream fall into the region between the electrodes of the electrodynamic trap. An alternating electric field of the quadrupole type in the internal volume of the electrodynamic trap creates the Gaponov-Miller force [L.D. Landau, E.M. Lifshits. Mechanics. M .: Nauka 1988, 215 pp.], Acting on charged particles and which is directed towards the central axis of a linear electrodynamic trap. Under the action of this force, the movement of particles in the direction perpendicular to the axis is inhibited and particles are trapped by the trap between its electrodes. To remove particles from the gas stream, an electric potential of the same sign as the particle charge is supplied to the electrode 7, due to which the particles begin to move from the electrode 7 in the direction of the receiving hopper 2. Thus, the particles are removed from the air stream. Particle-free airflow exits the exhaust outlet.

This method has been tested to remove positively charged particles from the air stream. In FIG. Figure 2 shows the histograms of the distribution of injected and removed particles by diameters d _p for the parameters in the experiment: air flow rate of 30 cm / s, electrodes 3-6 were cylindrical metal rods 20 cm long and 4 mm in diameter. A voltage of amplitude U = 11.7 kV and frequency f = 100 and 200 Hz was applied to electrodes 3–6; the potential at electrode 7 was 0.5 and 1 kV.

Claims (1)

A method for removing charged microparticles from a gas stream by an electric field of an electrostatic precipitator, characterized in that a quadrupole type electric field is used to capture charged particles, which forms a linear electrodynamic trap whose axis is perpendicular to the direction of the gas flow velocity, in which charged particles are captured without depositing them on electrodes and removal of trapped particles from the gas stream along the axis of the trap under the action of gravity and / or an additional constant about the electric field.

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