RU19642U1 - TWO STEP DUST CATCH - Google Patents

Abstract

1. A two-stage dust collector containing a series-connected source of dusty air, dust collectors of the first and second stages, as well as a draft device, characterized in that the source of dusty air is made in the form of a series-connected hopper of an electrostatic precipitator and a mixing chamber, to the second input of which a draft device made in the form of a compressor for compressed air, dust collectors of the first and second stages are made in the form of vortex dust collectors with two dust inputs pressure, connected to the inputs of the control system, the output of which is the movement of a control device installed on the lower inlet of the dust collector of the first cleaning stage. 2. The two-stage dust collector according to claim 1, characterized in that the dust-air flow control system is made in the form of a system with an intelligent phase module.

Description

Two-stage dust collector

The utility model relates to devices for collecting dust emissions generated during the production of the anode mass from petroleum coke and can be used in non-ferrous metallurps, as well as in other industries where dust collection equipment is used.

A known installation for the enrichment of bulk materials, including a two-stage separation of the gas-air mixture - graphite-containing dust emissions.

Graphite-containing emissions are collected at the places of their formation by local suction pumps and, due to the vacuum generated by the smoke exhaust, are sent sequentially to the first and second dust collectors (cyclones TsN-24 and TsN-11), where separation occurs. Post-treatment of finely dispersed components is carried out in an electrostatic precipitator.

In each dust collector, an adjustable intake of a gas-air mixture is taken from the total gas-air stream in an amount of 0.001-0.05 of the total flow rate of this stream.

This creates a pressure drop of 290-980 Pa in the first stage and 1470-2450 Pa in the second stage (see the description of the invention to copyright certificate No. 1273194 MKI V 07 V9 / 00, 03 V 9/04, publication 11/30/86).

The disadvantages of this invention include the use as dust collectors of cyclones that do not provide a high degree of purification and dust collection.

The proposed utility model is aimed at solving the problem of creating an effective cleaning of emissions, for example, coconut dust, by adjusting the ratio of the flow rate of air supplied to the dust collectors, and ensuring the stable operation of dust collectors.

This is achieved by the claimed combination of features.

In a two-stage dust collector containing a serially connected source of dusty air and dust collectors of the first and second stages, as well as a draft device, the source of dusty air is made in the form of a series-connected hopper electroMPK VOD 45/04

VO7V 9/00, VO39 / 04

filter and mixing chamber, to the second input of which a draft device made in the form of a compressor for receiving compressed air is connected. The first and second stage dust collectors are designed as vortex inertial dust collectors with counter-swirling flows with two dusty gas inlets, and pressure sensors are installed at the inlet of the first stage vortex inert dust collector. On the gas pipeline supplying the dusty mixture to the lower inlet of the first dust collector, a damper is installed connected to the output of the control system, the inputs of which are connected to the pressure sensors of the first inertial dust collector.

The dust-air flow control system is designed as a system with an intelligent phase module.

The technical result from the implementation of this utility model is as follows.

When cleaning air from coke dust, non-stationary working conditions of the first stage dust separator are often created due to the uneven operation of the compressor and the uneven supply of coke dust to the mixing chamber (due to the peculiarities of the technological process, as well as a high degree of caking of coke dust).

Devices with counter-swirling flows are sensitive to changes in the ratio of the flow rate of air supplied to the lower and upper inputs to the device, therefore, maintaining the optimal value of these parameters is required.

In order to maintain the optimal value of the air flow supplied to the lower and upper inlets of the first stage dust collector, which is 27% to the lower inlet and 73% to the upper inlet, in this utility model the air-dust mixture is supplied to the dust collector using compressed air, and the air flow to the upper and lower inputs are regulated by a control system, the output of which is the movement of the regulating device.

This ensures the stable operation of the dust collector and increases the cleaning efficiency.

The essence of the utility model is illustrated by the drawing, where in FIG. 1 shows a General view of the claimed two-stage dust collector.

The dust collector contains a source of dusty air, made in the form of an electrostatic filter hopper 1 and a mixing chamber 2 connected in series with it, which is connected to a draft device 3 made in the form of a compressor for receiving compressed air. The dust collector of the first stage 4 has sensors 5 and 6 at the lower and upper inputs of the apparatus, an adjustable damper 7, which is connected to the output of the control system 8. The axial pipe 9 of the air outlet of the cleaned dust collector of the first stage 4 is connected to the upper and lower

the dust collector inlets of the second stage 10, where post-treatment takes place and air is discharged into the aspiration system (not shown in the diagram).

The dust collector works as follows:

Coke dust from the hopper of the electrostatic precipitator 1 enters the mixing chamber 2. Using compressor 3, compressed air is supplied to the mixing chamber 2, which forms a dusty air mixture and prevents the caking of dust components. The dust-air mixture from the chamber 2 is supplied by the compressor 3 to the first cleaning stage to the dust collector 4. At the upper inlet to the dust separator 4, a pressure sensor 5 is installed, at the lower inlet - a pressure sensor 6. The dust separator of the first stage 4 is equipped with a control damper 7, which is controlled by the control system 8 with intelligent phase module. When changing the ratio of air flow rates noted by sensors 5 and 6, the signal from the sensors enters the control system 8, which transmits a command to the regulating device 7, which controls the flows in such a way that the ratio of the flow rate of the dust-air mixture supplied to the upper and lower inlets of the first stage dust collector is maintained at 25-28% on the lower input and 72-75% on the upper input.

The dusty air flow inside the dust collector of the first stage 4 acquires a helical motion, the flows move towards each other, and intensive dust separation occurs at the meeting point of the flows. Dust along the walls is lowered into the hopper of the dust collector of the first stage 4, and the cleaned air through the axial nozzle 9 is fed into the dust collector of the second stage 10, where it is refined, and then the air is fed into the aspiration system (or is vented to the atmosphere).

Dust from the hoppers of the dust collectors of the first stage 4 and second stage 10 is removed for further use or in the dump.

From the applicant:

General Director of Volgogradekotechser LLC

- V.N. Azarov (

Claims (2)

1. A two-stage dust collector containing a series-connected source of dusty air, dust collectors of the first and second stages, as well as a draft device, characterized in that the source of dusty air is made in the form of a series-connected hopper of an electrostatic precipitator and a mixing chamber, to the second input of which a draft device made in the form of a compressor for compressed air, dust collectors of the first and second stages are made in the form of vortex dust collectors with two dust inputs pressure, connected to the inputs of the control system, the output of which is the movement of a control device installed on the lower inlet of the dust collector of the first cleaning stage. 2. The two-stage dust collector according to claim 1, characterized in that the dust-air flow control system is made in the form of a system with an intelligent phase module.