RU2250798C1 - Method of purification of the air from aerosol particles by installations of a pressure pneumatic transportation of dispersible materials - Google Patents

Abstract

FIELD: natural gas industry; purification of gases from dispersible impurities.

SUBSTANCE: the invention is intended for purification of gases from dispersible impurities and may be applied in the pressure pneumatic transport systems and production lines of processing of dispersible materials mainly with non-stationary streams. The method of air purification provides for action of inertial forces on a dispersible material in a discharger, withdrawal of the air from the discharging gear and action of the centrifugal forces on the particles in the cyclone apparatus with consequent filtration of the air. Depending on a mode of transportation, 40-80 % of an air stream with the smaller content of the particles are removed from the discharging gear, run through the cyclone apparatus, from which up to 30-90 % of the air stream with the smaller content of the particles fed into the cyclone apparatus are withdrawn and directed for filtration, and 10-70 % from the air stream with high content of the particles fed into the cyclone apparatus are through a damper of braids removed in the filtering dust collector of the cyclone apparatus. Other part of the air stream in amount of 20-60 % with high concentration of the particles is removed from the discharging gear into a collector of the dispersible material, whence it is removed into the cyclone apparatus, from which up to 10-50 % of the air stream with the small contents of p[articles fed into the cyclone apparatus are removed and directed for filtration, and 50-90 % of the air stream with a high content of the particles fed into the cyclone apparatus through the damper of braids removed into the filtering dust collector of the cyclone apparatus. The technical result consists in the continuously high efficiency of trapping of the thinly dispersed materials at different modes of transportation at the constantly high productivity with preservation of the service life of the bag filters.

EFFECT: the invention ensures continuously high efficiency of trapping of the thinly dispersed materials at different modes of transportation and constantly high productivity with preservation of the service life of the bag filters.

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Description

The invention relates to techniques for cleaning gases from dispersed impurities and can be used in pressure pneumatic conveying systems and processing lines for processing dispersed materials, mainly with unsteady flows.

A known method of purification of gases from aerosol particles in pressurized pneumatic conveying systems of dispersed materials, including the action of inertial forces on the dispersed material in the unloader and its subsequent cleaning in a bag filter / Urban J. Pneumatic transport. - M.: Mechanical Engineering, 1967. - 266 p. /.

The disadvantage of this method is the low productivity of the apparatus due to the need to maintain low gas flow rates (0.02-0.05 m / s) when passing through the filter, high dust loads on the filter, short life, the need for regular filter regeneration.

There is also a known method of gas purification from aerosol particles in pressurized pneumatic conveying systems of dispersed materials, including the action of inertial forces on the dispersed material in the unloader, the removal of air from the unloader and the action of particles of centrifugal forces in a cyclone apparatus followed by air filtration / Malis M.Ya. Pneumatic conveying of bulk materials at high concentrations. - M.: Mechanical Engineering, 1969. - 183 p. prototype.

The disadvantage of this method is the low efficiency of the cyclone apparatus at various modes of transportation and, as a result, clogging of the filters with their subsequent destruction and disruption of the pneumatic conveyor line.

The objective of the invention is to increase the efficiency of the system depending on the mode of transportation by redistributing the flows in the unloader, redistributing the flows in cyclones with flow-slowing elements to calm the bundles, which reduces the dust load on the filters.

The proposed method of purifying air from aerosol particles in pressurized pneumatic conveying systems of dispersed materials includes the action of inertial forces on the dispersed material in the unloader, the removal of air from the unloader and the action of particles of centrifugal forces in a cyclone apparatus, followed by air filtration. Depending on the mode of transportation, 40-80% of the air stream with a lower content of particles is discharged from the unloader, passed through a cyclone apparatus with elements that contribute to the intensification of the formation of a dispersed medium and calming the bundles, of which 30-90% of the air entering the cyclone with a low content of particles output for filtering, and 10-70% of the air received in the cyclone with a high content of particles through the dampener of the bundles is removed to the filter dust cyclone receiver. 20-60% of the air received in the unloading device with a high concentration of particles is discharged from the unloading device to the dispersed material receiver, from where it is discharged into a cyclone apparatus with elements that contribute to the intensification of medium formation of particles and calming the bundles, of which 10-50% of the cyclone , with a low content of particles are removed for filtration, 50-90% of the air coming into the cyclone with a high content of particles through the dampener of the bundles is removed to the filter dust receiver.

The drawing shows a diagram of an installation for implementing the method.

The material is transported by air and enters the unloader 1 connected to the receiver 2. The unloader 1 is connected through a nozzle to a dedusting unit consisting of a cyclone 3 with a damper 4 and a filter dust receiver 5. A part of the material with a stream from cyclone 3 enters the filter 6. Separated from material in the filter 6 and the filter dust receiver 5 through the dust outlet flows into the receiver 2. The receiver 2 through the pipe is connected to a dust collection unit consisting of a cyclone 7 with a damper 8 and a filter dust receiver 9. Cha be a material with a stream from the cyclone 7 is supplied to the filter 10. The liberated stream of filter material 10 and filter dust receiver 9 via pylevyvodnye heat enters the receiver 2. For regulating the air flow in the cyclone 3 installed on the flow sensors 11, 12 are installed; on cyclone 7 - flow sensors 13, 14.

The method is as follows.

From a silo (a warehouse of powder material, for example cement), the material in a piston or aerosol state is transported by air in the amount of Qp to the unloader 1, where it is released from the carrier stream and enters the receiver 2.

Air with a lower content of particles from unloader 1 in the amount of Qв, depending on the mode of transportation, enters cyclone 3 with a damper 4, where it is divided into two flows: air with a low content of particles in the amount of q _is discharged to filter 6, and air with a high content of particles in the amount of QB-q _in output through the damper 4 in the filter dust receiver 5.

Air with a high content of particles from the unloader in the amount of Qn is directed to a receiver 2, where it is freed from clots of particles and then to cyclone 7 with a damper 8, in which it is divided into two streams: a stream with a low content of particles in the amount of q _{n is} taken out for filtration in filter 10, and air with a high content of particles in the amount of Qn-q _{n is} discharged through a damper 8 into the filter dust receiver 9.

In this case, the regulation of air flows in cyclone 3 is carried out using flow sensors 11 and 12, and in cyclone 7 through flow sensors 13 and 14.

The indicated ranges of flow rates are associated with the mode of transportation of powder material from silo to unloader 1. When the content of the material in the silo exceeds 10% of its volume, the material in the transport pipeline moves with pistons (plugs) and the average concentration of particles in the air is more than 20 kg / kg of air / Malevich I.P., Seryakov BC, Mishin A.V. Transportation and storage of powdered building materials. - M .: Stroyizdat, 1984. - S.93-97, S.111 /.

Moreover, in the period of time the piston arrives, the amount of incoming air is minimal, and in the intervals between the pistons it is maximum. The particles contained in the air are generally less than 1 micron in size. In this mode of transportation of dispersed material, air from the unloader 1 in the amount of Qв = (0.4-0.6) Qp is sent to cyclone 3 and in the amount of q _в = (0.3-0.4) Qв filter 6, the flow in quantity Qв-q _в = (0.7-0.6) Qв with an increased concentration of particles is directed through a damper to slow down the flow and calm the bundles 4 into the dust filter receiver 5.

Air from the unloader 1 with a high content of particles in the amount of Qн = Qp-Qв = (0.6-0.4) Qp is sent to the receiver 2 and then to cyclone 7, from which air in the amount of q _n = (0.2-0 , 3) Qn is output for filtration to the filter 10, and another stream through the damper 8 in the amount of (0.8-0.7) Qn is sent to the filter receiver 9.

With this redistribution of flows, material does not hang in the unloader 1, the formed bundles are separated from the stream and transported to the bottom of the filter receivers / Ostrich B. Industrial gas cleaning. Per. from English - M .: Chemistry, 1981. - 616 p. /. Dust loads on the filters are small, and the system works stably.

When the material content in the silo does not exceed 10% of its volume, the material in the transport pipeline moves in the form of a suspension (aerosol - transport) with an increased air flow rate. The dust in the streams at the outlet of the unloader and receiver bin has a fractional composition close to the initial one, i.e. most dust contains particles larger than 2 ^-X microns. In this case, Qв = (0.7-0.8) Qp, q _в = (0.6-0.9) Qв, Qн = (0.3-0.2) Qp, q _н = (0.1 -0.5) Qn.

With this redistribution of flows, dust does not hang in the unloader, cyclones 3 and 7 do not clog, operate stably, efficiently, and the dust load on filters 6 and 10 is reduced.

An example embodiment of the invention

Example 1

In production conditions, part of the dusty air was taken from the unloader and it was cleaned by a known and proposed method.

1.1. We used a cyclone type SK - TsN - 34, in which the diameter of the dust outlet is less than the diameter of the gas outlet pipe; the receiver is made of transparent, rigid and impermeable material / Guide to dust and ash collection / Under. ed. M.I. Birger, A.Yu. Waldberg, B.I. Myagkov and others. Under the general editorship. A.A. Rusanova. - 2 ed. - M .: Energoatomizdat, 1983.- 312 p. /.

The pressure in the unloader ranged from 0.2-1.2 kPa. Cyclone dust retention efficiency was determined by the formula

,

- привесы фильтра и приемника после пропускания запыленного воздуха через циклончик.Where

,

- weight gain of the filter and receiver after passing dusty air through the cyclone.

Observations and measurements showed the following results.

When small amounts of air with dust enter the cyclone, there is no dust entering the receiver; particles are redistributed over the volume of the cyclone, partially removed, partially adhered to the walls. The dust is fine, has a median size of δ _m <2 μm. Upon receipt of large portions of air, the air picks up dust on the walls, in volume and transports it to the receiver. However, due to the weak formation of harnesses, it was visible that the dust in the receiver was precipitating unsatisfactorily. The dust retention efficiency did not exceed 45%. Dust buildup was observed in the area of the dust outlet.

When using a receiver with flexible filtering surfaces, “collapse” was observed upon receipt of large portions of air, which is explained by the occurrence of rarefaction in the dust outlet. This leads to the complete ablation of the material from the cyclone to the filter (η = 0).

1.2. According to the proposed method, the flow is directed to a conical cyclone, to which a damper was attached from the side of the dust outlet to slow down the flow and calm the bundles, 70-80% of the incoming air was sent to the filter receiver. In this case, the cleaning process was stable, the dust-holding efficiency of the cyclone was more than 98%.

Example 2

In production conditions, the working air was cleaned in the installation of cement pneumatic transport in the piston mode according to the proposed method (drawing).

The air from the unloader 1 with a high concentration of particles in the amount of Qн = (0.4-0.6) Qp passed to the receiver 2, where it was freed from clots of particles and then to cyclone 7. From cyclone 7, air with a lower content of particles in the amount of q _n = (0.4-0.5) Qn was removed for filtration at 10, and air with an increased concentration of particles through flow damper 8 in the amount of (0.6-0.5) Qn to the filter receiver 9. Air from the unloader 1 with less particle concentration in the amount of Qв = (0.6-0.4) Qp passed in 3 and then was divided into two flows: a stream with a lower concentration of particles in the amount of q _a = (0.3-0.4) Qv directed to filter 6, and a rate of flow Q B = _a-q (0,7-0,6) Q B through the flow damper 4 in filter receiver 5. This flow ratio the process of transporting the material and purifying the air was stable and efficient: there was no material hanging in the unloader, the resistance of the purification system increased by no more than 50%; the removal of material into filters 6 and 10 was less than 0.003% of the amount received in the unloader, i.e. it is permissible to work without filters.

Example 3

In laboratory conditions, air was cleaned in stationary streams at various concentration ranges and air flow rates by the proposed method. Dust was used - cement with a median particle size of δ _m = 23 μm, in which the particle content of less than 2 μm was 2%.

At cyclonic entry speeds of 10–20 m / s and dust concentrations of 5–50 g / m ^3, high dedusting efficiency (η> 99%) is achieved when q _is <0.9Qv.

At cyclonic entry speeds of 4-6 m / s and concentrations of 10-100 g / m ^3, satisfactory operation and high efficiency are achieved when q _n = (0.3-0.1) Qn, i.e. most of the air with a high concentration of particles should enter the filter receiver.

The positive effect of the invention lies in the continuous high efficiency of the capture of finely dispersed materials at various modes of transportation at a consistently high performance while maintaining the long life of bag filters.

Claims (1)

A method of purifying air from aerosol particles in pressure pneumatic conveying systems of dispersed materials, including the action of inertial forces on the dispersed material in the unloader, air outlet from the unloader and the action of centrifugal forces on particles in a cyclone apparatus, followed by air filtration, characterized in that 40-80% of the flow air with a lower content of particles is removed from the unloader, passed through a cyclone apparatus with elements that contribute to the intensification of the tow formation of a dispersed medium and calm Ia tows, from which 30-90% of the incoming air to the cyclone with a low content of particles outputted to filtering, and 10-70% of the incoming air to the cyclone with a high content of particles through the damper wire harnesses outputted to filter dust cyclone receiver; 20-60% of the air received in the unloading device with a high concentration of particles is discharged from the unloading device into the dispersed material receiver, from where it is discharged into a cyclone apparatus with elements that contribute to the intensification of the medium formation of particles and calming the bundles, of which 10-50% of the cyclone air with a low content of particles is removed for filtration, 50-90% of the air received in the cyclone with a high content of particles through the dampener of the bundles is removed to the filter dust receiver.