RU2314860C2 - Device for purification of the gases - Google Patents

Abstract

FIELD: heat-and-power industry; metallurgy industry; building industry; other industries; devices for purification of the gases from the dust.

SUBSTANCE: the invention is pertaining to the field of purification of the gases from the dust, in particular, to purification of the flue gases of the coal-fired boiler aggregates and may be used in the power, metallurgical, building industries, where the wet dust-catching is used. The invention provides, that the dust-catching device using the method of the wet purification is supplied with the protractile blades of the swirler with the adjustable clearance between the body and the blade, the drop-catcher of the tent-roofed type providing at the low aerodynamic resistance the high efficiency of catching of the drop moisture. The device components may be made both from titanium and from the glass-reinforced plastics, which makes them cheaper. The efficiency of the dust catching makes up to 99.9 %.

EFFECT: the invention ensures the efficiency in purification of the gases in the dust catching up to near hundred percent.

6 cl, 2 dwg

Description

The invention relates to wet dust collecting devices using water-gas emulsion and can be used in energy, metallurgy, construction industry and other industries for deep cleaning of gas emissions from dust and partial cleaning of sulfur dioxide.

Known devices for wet cleaning of gases from dust, consisting of a housing, inside which there are foaming or emulsion-forming elements in the form of gratings or swirls of various types (Handbook on dust and ash collection edited by A. Rusanov, 1983, 112 pp. ., journal "Electric stations" No. 5 for 1997).

The closest in technical essence and the achieved result is a device for gas purification (emulsifier), described in patent No. 2132220 of 10.21.98, consisting of a round casing made on the basis of a scrubber, an inlet and an outlet for gas inlet and outlet. In the body of the scrubber, in the aerodynamic niche, a swirler is installed, which is the initiator of emulsification, and a water distribution system. Above them there is a tent-type louvre droplet eliminator with blades located along a helical line.

Having high efficiency (degree of purification of more than 99.5%), such devices did not exhaust the possibility of increasing it.

Industrial designs of devices showed the possibility of achieving a degree of purification in the calculated modes of more than 99.9%.

The disadvantages of this type of device include:

- not a wide range of optimal gas flow rates, which ensures maximum design efficiency;

- a sharp increase in the resistance of the swirl when reaching in its channels gas velocities exceeding the calculated;

- not fully utilized the possibility of increasing the efficiency of sulfur dioxide capture in plants of this type;

- the manufacture of the apparatus requires a significant amount of titanium, which increases the cost of gas purification;

- the use of composite materials (fiberglass, etc.) is not structurally developed;

- high aerodynamic resistance.

The aim of the invention is to further increase the efficiency, reliability, cheaper process of cleaning gases from dust and eliminate the noted disadvantages.

These goals are achieved by the fact that (figure 1),

- the blades of the swirl are retractable with an adjustable gap between the body and the blade, which makes it easy to change the blades in case of wear and to make them not from expensive titanium, but from fiberglass and other relatively cheap non-metallic materials (ceramics, graphite plastic, etc.). Retractable vanes make it easy to change the gap between the end of the vanes and the emulsifier body. The size of the gap is the determining value for many parameters of the emulsifier: performance, efficiency, dimensions, etc.

- the niche in which the swirl is installed is formed by a gas distribution diaphragm (2) and a water-reflecting cornice (6);

- the water-reflecting cornice (6) consists of two elements - the upper ring, which is tightly attached to the body, and the lower guide cone, which supplies water to the water distribution plate. The irrigation of the swirler in this case increases by 2-5 times;

- the swirl channels are made of variable cross section due to the installation of the conical base of the swirl blade of the swirl. This allows you to provide optimal gas speeds when changing their volume due to cooling or heating during movement in the swirl channels;

- the pulp is drained from the gas distribution diaphragm through slots in the sides of the overflow shell, which contributes to uniform irrigation and cooling of the gases entering the apparatus;

- the capacity of the spillway device is designed in such a way that together with the gas distribution diaphragm (2) and spillway shell (12) form a basket in the active zone, which is equipped with granules of sorbent, catalyst, neutralizer, which help to capture unwanted gases and work effectively in the active zone of the device, including volume of phase inversion in the swirler;

- a cone is installed inside the inlet gas duct, restricting the penetration of moisture inside, equipped with periodic washing nozzles.

Figure 1 schematically shows a vertical section of the proposed dust collector.

The device consists of a cylindrical body (1), which can be used as a scrubber of the existing wet dust collection system, an inlet duct (11) introduced tangentially into the emulsifier body and provided with a cone (13), which limits the penetration of moisture into the duct and eliminates ash deposition . The gas duct from the cone to the emulsifier body is lined with an acid-resistant tile and has periodic washing nozzles (16). Inside the emulsifier body, a gas distribution diaphragm (2) is installed in front of the swirl (4), which simultaneously collects the pulp and evenly distributes it through the slots in the drain shell (12) along the perimeter of the emulsifier body, which cools the incoming gases with water jets, reduces the change in their volume when moving in the channels of the swirl and reduces its resistance.

In the installation zone of the inclined blades of the swirl (4) there is a vortex niche (3) formed by a swirl and a water-reflecting cornice (6), which is made of titanium sheet or fiberglass, which allows you to keep the scrubber body unchanged and thereby reduce the cost of the apparatus.

As a result of the interaction of the annular gas-liquid flow with a two-element reflective cornice (6), a horizontal vortex flow forms in the form of a rotating torus, which ensures high mass transfer and degree of purification.

The water supply to the blades of the swirl is carried out by means of a water distribution plate (5), filled with water, and along the edges provided with slots (15), the number of which is a multiple of the number of blades (figure 2).

Above the two-element reflective cornice (6), which ensures pulp return and drop eliminator unloading, a number of plane-flare nozzles (7) for feeding the apparatus with water are flush with the lining. A continuous network of clean water droplets cuts off the area of the droplet eliminator from the emulsifier, which contributes to the deposition of droplets of dirty water carried out from the active zone and protects the droplet eliminator from ash drift.

The droplet eliminator (8) is made of a tent construction with corner blades located along the helical line of the cone, and the end face of the corners is adjacent to the vertical walls of the scrubber, which prevents secondary droplet drop. The aerodynamic drag of the droplet eliminator does not exceed 3-5 mm water column

The high efficiency of the droplet eliminator allows you to fill the active zone with finely dispersed moisture and provide a consistently high coefficient of ash collection at a relatively low aerodynamic drag of the active zone.

Behind the droplet eliminator there is a shield (9), which prevents moisture from rising along the walls of the housing (1) into the outlet duct (10).

The device operates as follows: the flue gases from the boiler units enter the apparatus body (Fig. 1) from the inlet duct (11) under the gas distribution diaphragm (2) of the emulsifier, where the formed pulp is evenly distributed through the slots in the overflow shell. In this zone, up to 88% of dust is captured.

After the gas distribution diaphragm, partially purified gases enter a vortex niche, where a phase inversion process takes place in the swirl channels, as a result of which the finest dust fractions are captured. Gases saturated with moisture are freed from contaminated water in the water-repellent cornice (6) and are additionally washed with water from flat torch nozzles (7). After the droplet moisture is completely removed in the droplet trap (8), the purified gases enter the gas duct (10). Trapped ash in the form of pulp is removed through a water trap (14).

According to tests of an industrial installation on a PK-24 boiler, ash recovery efficiency of 99.8-99.9% was achieved with an output dust content of gases of 40-70 mg / nm ³ and an input dust content of gases of 20-40 g / nm ³ , aerodynamic resistance of the apparatus 120- 170 mm water column The high mass transfer of the vortex zone, as well as additional pulp recirculation, makes it possible to capture from 10 to 25% or more sulfur dioxide, depending on the composition of the ash.

Claims (6)

1. A device for cleaning gases from ash, containing a cylindrical body, gas inlet and outlet nozzles, an aerodynamic niche with a swirl located in it, a water-dispensing system filled with a water-gas emulsion in the form of a disk-shaped water distributor filled with water, with perimeter slots, a droplet eliminator and a water trap for draining pulp, characterized in that the swirl blades are made retractable with an adjustable gap between the body and the blade. 2. The device according to claim 1, characterized in that the niche in which the swirl is installed is formed by a gas distribution diaphragm and a water-reflecting cornice. 3. The device according to claim 1, characterized in that the water-repellent cornice is made of two elements: an upper ring that fits tightly to the body, and a lower guide cone that supplies water to the water-distributing plate. 4. The device according to claim 1, characterized in that the swirler channels are made of variable cross-section along the length due to the installation of a conical base bearing the swirler blades. 5. The device according to claim 1, characterized in that the capacity of the spillway device formed by the gas distribution diaphragm and spillway shell is provided with sorbent, catalyst or neutralizer granules. 6. The device according to claim 1, characterized in that a cone is installed inside the inlet duct, restricting the penetration of moisture into the duct, equipped with periodic washing nozzles at the top.

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