SU1719088A1 - Method of regenerating electrical filters with receiving electrodes, and device therefor - Google Patents

Abstract

The invention relates to gas cleaning and can be used in various industries for cleaning gases from dust. The aim of the invention is to increase the efficiency of regeneration of electrostatic precipitators. The method of regeneration of electrostatic precipitators with permeable precipitating electrodes is carried out by reverse pulse blowing and shaking. The pulsed blowdown is carried out with a series of short-duration pulses of increasing porosity synchronized with shaking, the shaking being carried out by removing and restoring the voltage of the collecting electrodes. A device for regeneration of electrostatic precipitators with permeable precipitating electrodes, containing a metal hermetic case, a system of shorting electrodes, hollow flat collecting electrodes, louver dampers, blind metal partitions, purge air supply nozzles, high-voltage insulators and a storage bin, are installed in the form of rectangular frames installed opposite the corona electrodes on the side of pure gas for each half of the planar in a staggered order across the motion of the gas, with the cavity of the precipitating electrode divided in half by means of a louver damper. 2 sec. f-ly, 1 ill.

Description

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The invention relates to gas cleaning and. can be used in various industries for cleaning dust from gases.

A known method of filter regeneration by its deformation and simultaneous reverse blowing / A device that implements the above mentioned method of regeneration contains filter sleeves, in the upper part of which a mechanism is installed that deforms the sleeve, as well as a purge air supply system from the clean gas side.

However, the deformation forces are directed tangentially to the surface being cleaned, i.e. destruction of the deposited layer can occur under the condition that the cohesive forces tangent to the surface of the filter septum are overcome, which are usually much greater than the forces directed normally. In this connection, shaking is effective under the condition that a shaking impulse develops with an acceleration of 12-20 d, which leads to rapid mechanical wear of the precipitation electrode, moreover, the removal of the dust layer is uneven over the entire surface.

Closest to the invention is a method for regenerating an electrostatic precipitator by shaking and simultaneously blowing back. The effect is achieved by cracking the layer of precipitated dust as a result of the deformation of the dust collecting surface and removing it due to the backward flow of air through the pores of the air material. A device that implements this method contains a metal case, corona and collecting electrodes, louvre and metal partitions, purge air supply nozzles, high-voltage insulators and a storage bin.

The disadvantage of this method is that the electric dust precipitation mechanism and the filtration mechanism do not work simultaneously, and this implies the creation of two separate devices for their implementation and thereby reduces the regeneration efficiency by reverse blowing, so that the propagation vector of the elevated pressure zone when a compressed pulse is applied air is parallel to the plane of the collecting electrodes in the first electrodeposition zone.

The purpose of the invention is to increase the recovery efficiency of the electrostatic precipitator. The proposed regeneration method and device for its implementation provide better cleaning of the filter surface and less slippage of particles at the initial time after regeneration due to uniform cleaning of the surface from dust over the entire area of the filter element.

The goal has been achieved by a method of regenerating electrostatic precipitators with permeable collecting electrodes by reverse pulsed blowing and shaking, in which pulsed blowing is performed by a series of short-duration pulse-width pulses synchronized with shaking, while shaking is carried out by removing and restoring tension of the collecting electrodes.

The difference of the method is that the pulses of the purge air are supplied from the increasing of the duty cycle from the beginning of the purge, synchronized in time with shaking, this allows to better clean the surface of the precipitation electrode from

precipitated dust and does not lead to rapid deterioration of the precipitation electrode.

Such a method can be carried out in a device containing metallic

hermetic housing, inside which is located the system of corona electrodes and hollow flat collecting electrodes, made of woven metal mesh. Inside each precipitation electrode, a louver damper is installed, which in the closed state divides the electrode volume in half. At the same level, deaf metal partitions are installed between adjacent collecting electrodes. Thus, the space between the collecting electrodes is divided into two parts by stationary partitions, and the internal cavity of the collecting electrode, if necessary,

0 is divided into halves with louver shutters. Corona electrodes are located both inside the precipitation electrode and in the space between them, in a checkerboard pattern. Inside sedative

5 electrodes and in the space between them electromagnetic vibrators are located, connected to grids of collecting electrodes with the help of rectangular frames. The device is equipped with feed nozzles.

0 purge air. On the upper cover of the filter housing there are high voltage insulators, on which rectangular frames with collecting electrodes from a metal grid are fixed. For

In the accumulated dust accumulation in the lower part of the housing there is a storage bin. New in the design is the introduction of electromagnetic vibrators, made in the form of rectangular frames,

0 installed opposite the corona electrodes from the side of the pure gas, for each half of the flat precipitating electrode, in a staggered order across the movement of the gas, the cavity of the precipitating electrode divided in half by a positive valve, this allows the dust layer to be removed evenly from the entire surface of the precipitating electrode .

 In existing facilities, there remains the problem of the quality of regeneration, for example, in the device, the cleaning of the collecting electrodes of the first zone and the filters of the second zone is carried out with a single blowing device, and if the filter

5 is made perpendicular to the working surface, through the filter material and is of high quality, then this same purge gas flow is unlikely to be able to effectively clean the longitudinal flat collecting electrodes of the first zone

electrodeposition, which should lead to rapid dust overgrowth, and, consequently, inefficient operation of the first filter zone. In the second device, due to the damping properties of filter materials, dust separation during shaking occurs unevenly. Basically, the areas adjacent to the attachment points are cleaned and, as a result of this, at the first time point, an overshoot of particles will be observed in these filter sections due to the multiply increased filtration rate.

The proposed regeneration method and device for its implementation are free from the listed drawbacks. The permeable precipitation electrode combines the functions of a filter septum and a planar precipitation electrode, therefore, increasing the efficiency of its regeneration does not cause any particular difficulties. Due to the fact that the electromagnetic vibrator acts on the grid electrode through a rectangular frame and these effects are combined with the supply of compressed air pulses, the manifestation of the damping effect of the metal mesh is negligible, which allows for uniform cleaning of the surface.

The drawing shows the design of the proposed device.

The device contains a metal sealed enclosure 1, inside which is located a system of corona electrodes 2 and hollow flat collecting electrodes from a metal mesh 3, made in the form of rectangular prisms, two longitudinal side surfaces of which are made of metal woven mesh, others (transverse) of metal are deaf . Inside each precipitation electrode 3, a louver flap 4 is installed, which in the closed state divides the volume of the precipitation electrode 3 in half. At this same level between the adjacent precipitation electrodes 3, metal metal partitions 5 are installed. Thus, the space between the precipitation electrodes 3 is divided into two parts by stationary partitions, and the internal cavity of the precipitation electrode 3 can

if necessary, be divided into: halves with louver shutters 4. Corona electrodes 2 are located both inside the precipitating electrode 3 and in 5 spaces between them, in a checkerboard pattern. Inside the precipitation electrode 3 and in the space between them are electromagnetic vibrators 6. connected to the grids of the dropping electrodes 3.

0 by means of rectangular frames 7. The device is equipped with purge air supply nozzles 8. High-voltage insulators 9 are located on the top cover of the housing 1, on which are mounted straight carbon frames 7 with collecting electrodes 3. There is a bunker in the lower part of the housing 1 - drive 10 ..

Claims (2)

Formula of gain 0 1. Method of regeneration of electrophiles with permeable collecting electrodes by reverse pulsed blowing and shaking, so that, in order to increase 5, the recovery efficiency of the electrostatic precipitator, pulsed blowing is carried out by a series of short pulses of increasing porosity, which are synchronized with the moment of shaking, while shaking is carried out by removing and restoring the tension of the precipitating electrodes. 2. A device for regenerating electrostatic precipitators with permeable precipitation 5 electrodes containing a metal sealed enclosure, a system of corona electrodes, hollow flat collecting electrodes, louver flaps, blank metal partitions, purge air supply nozzle, high-voltage insulators and a storage bin, characterized in that it is equipped with electromagnetic vibrators - made in rectangular frames installed opposite the discharge electrodes from the side of the pure gas for each half of the planar collecting electrode in a staggered order across gas, the cavity of the precipitator electrode is divided in half by means of a shutter valve. with sh 9 g, L ten