SU806069A1 - Electric filter for gas scrubbing - Google Patents

Description

The invention relates to wet electrical cleaning from dust and harmful chemical impurities of technological and aspiration emissions.

Wet electrostatic precipitators are known, the precipitation electrodes of which have a special surface that facilitates the spreading of irrigating liquid over the precipitation surfaces. In this device, the precipitation electrodes are made of perforated material, the crumbling liquid is supplied to the precipitation electrodes in the form of a film from a trench filled with porous material [1J.

An electrostatic precipitator is known in which precipitation electrodes are in the form of cylinders made of porous permeable plastic surrounded by perforated steel. Irrigating fluid passes through the channels made in the body of the precipitation electrodes, and flows in the form of a film on their outer surfaces [2].

However, in known electrostatic precipitators, periodic cleaning of the electrodes is not provided. In addition, in order to create a continuous film on the precipitation electrodes, a very large number of starting costs of the irrigating liquid are required, which do not always guarantee the absence of wetted areas.

The purpose of the invention is to simplify the periodic cleaning of the precipitation and corona electrodes, as well as to improve the wetting of the precipitation surfaces when starting the electrostatic precipitator.

This goal is achieved by the fact that in addition to the film irrigation system, the precipitation electrodes are equipped with an auxiliary nozzle irrigation system, which is mounted in their body in the form of a spatial lattice.

The drawing shows the cell electrodes of the proposed electrostatic precipitator for wet gas purification.

The corona electrodes 1 are located between the flat deposition electrodes 2, which are arranged as follows. At the top of these electrodes is a pressure collector 3 for supplying irrigation fluid during normal operation of the electrostatic precipitator. The liquid exits the “collector through a slot or holes” 4, passes through a layer of porous ma-3® Series 5 (for example foam rubber) and is uniformly poured onto the “outer precipitation perforated electrode surface through a removable perforated cover 6. The lower narrowed part of the electrode is connected to the tray 7 to collect sludge water. Inside the precipitation electrode is a nozzle irrigation system 8, which simultaneously performs the functions of a spatial stiffness lattice for the construction of the entire electrode. The nozzles 9 are flush with the outer surface of the electrode made of perforated metal foil. Part of the nozzles 10 is located in the tray · 7 and is intended for periodic cleaning of this tray. Pure water is supplied to the nozzle irrigation system through the nozzle 11. The inner space of the precipitation electrode is filled with porous material, for example, foam.

The operation of the proposed device is as follows.

Dust particles, charging in the corona discharge field created in the interelectrode gap, move to the precipitation electrode 2, settle on its working surfaces, from where they are washed off by a continuous film of water, into the tray 7 and removed outside the apparatus.

To irrigate the precipitating surfaces of the electrostatic precipitator during normal operation, recycled (sludge) water can be used. In this case, the layer of porous material 5 eventually clogs with 35 suspensions. To regenerate this layer, the pressure in the manifold 3 is pulsed, the material 5 is compressed and the sludge accumulated in it is squeezed out through the perforations of the removable cover 6 4Q. If necessary, material 5 can be replaced with a new one.

'The nozzle irrigation system runs on clean water and is switched on periodically: a) during the start of the electrostatic precipitator to facilitate wetting of dry precipitation surfaces; b) for cleaning the precipitation and corona electrodes (the electrostatic precipitator is de-energized and switched off by gas), while the nozzles of one precipitation electrode clean the precipitating surface of the other and simultaneously wash off dust deposits from the corona electrodes (the electrostatic precipitator is de-energized and disconnected by gas ^, while the nozzles of one precipitation electrode they clean the precipitating surface of another and at the same time wash away dust deposits from 5 corona electrodes.

Thus, the electrostatic precipitator has the following advantages:

1. For continuous flushing of precipitation surfaces

Yu contaminated water (irrigated liquid).

2. During the start-up of the electrostatic precipitator, the complete wetting of the dry precipitation surfaces is guaranteed by the re-enrichment nozzle irrigation system.

3. For the exclusion of manual labor during the inevitable periodic cleanings of electrodes in precipitation

2Q electrodes mounted nozzles.

These advantages determine the effectiveness of the proposed electrostatic precipitator, facilitating periodic cleaning of the electrodes, providing a stable film of irrigating liquid on precipitation surfaces, etc.

Claims (2)

(54) ELECTROFILTER FOR WET GAS CLEANING mbrno poured onto the outside of the protective perforated electrode surface through a removable perforated fender 6. The lower constricted part of the electrode is connected to the tray 7 for collecting sludge water. Inside the precipitation electrode is a spray irrigation system 8, which simultaneously performs the functions of a spatial stiffness grid for the design of the entire electrode. Shapes 9 are flush with the outer surface of the electrode, made of perforated metal foil. A portion of the nozzles 10 is located in tray 7 and is intended for periodic cleaning of this tray. Pure water is supplied to the spray irrigation system through the fitting 11. The internal space of the sediment electrode is filled with a porous material, such as foam plastic. The operation of the proposed device is as follows. Dust particles, charged in the field of a corona discharge created in the interelectrode gap, move to the precipitation electrode 2, are deposited on its working surfaces, from where they are washed away with a continuous film of water in the tray 7 and out of the apparatus. For irrigation of precipitators of the electrostatic precipitator during the normal mode of its operation, recycled water can be used. In this case, the layer of porous material 5 will eventually become suspended. To regenerate this layer in the collector 3, the pressure is pulsed, the material 5 is compressed and the slime accumulated in it squeezes the removable lid 6 out through the perforations. If necessary, material 5 can be replaced with a new one. The spray irrigation system operates with clean water and is turned on periodically: a) during the start-up of the electro-filter to facilitate wetting of dry precipitating surfaces; b) for cleaning the precipitation and corona electrodes (the electrostatic filter is de-energized and disconnected by gas), while the nozzles of one of the collecting electrode clean the sedimentation surface of the other and at the same time wash off the dust deposits from the corona electrodes and the gas filter turns off the deposition surface of the other and at the same time wash off the dust deposits from the corona electrodes. Thus, an electrostatic precipitator has the following advantages: 1. Contaminated water (irrigated liquid) can be used to continuously draw down precipitating surfaces. 2. During the start-up of the electrostatic precipitator, the complete wetting of the dry precipitation surfaces is guaranteed by an ejection nozzle irrigation system. 3. To eliminate manual labor during the inevitable periodic cleaning of the electrodes, nozzles are built into the collecting electrodes. These advantages determine the effectiveness of the proposed electrostatic precipitator, facilitating periodic cleaning of the electrodes, providing a stable film of irrigating liquid on sensitive surfaces, and others. Formula of the Invention Electro-filter for wet gas cleaning, including a housing with inlet and outlet nozzles, hollow collecting electrodes with a perforated surface filled with porous with a film irrigation device, corona electrodes and a collector for collecting sludge water, distinguish This is due to the fact that, in order to simplify the periodic cleaning of the corona and collecting electrodes and to improve the wetting of dry precipitation surfaces during the start of the electrostatic precipitator, the collecting electrodes are equipped with a nozzle irrigation system made in the form of a spatial grid. Sources of information taken into account in the examination 1.Patent of Switzerland No. 362682, cl. 12 e 5, 15.08.G2. 2. US patent number 3570218, cl. 55-118, 16.03,71. 7.44