SK105597A3 - A method for removing solid particles from gases and apparatus for performing the method - Google Patents

Abstract

The method of removing solid particles from gases consists in the gas flowing against at least one system of several water films placed in one plane transversely to the direction of gas flow, whereby gaps for gas passage are formed between the individual water films, created by spraying a water stream with a speed of 0.5 to 30 m/s fed to the targets, at a distance from the target where the water films break up. The device for carrying out the method consists of a pipe (4) for flowing gas, in which there is at least one system of several nozzles (1) arranged in one plane of the cross-section of the pipe (4), the nozzles (1) are provided with a water supply, the diameter of the nozzles (1) d is 2 to 50 mm, a cylindrical target (2) with a diameter of 1.2 to 5 d is placed opposite each nozzle, the impact surface (5) of which is flat or convex, the radius of the spherical convex surface (5) of the target (2) being greater than the diameter of the target (2) and the distance of the target from the nozzle mouth being greater than 1 mm and the outlet of the nozzles (1) is in the direction of gas flow or against the direction of gas flow. The nozzles (1) are placed on the distribution pipe (3) and the targets (2) are placed opposite the openings of the nozzles (1) on a beam (14), which is connected to the distribution pipe (3) by supports (15), which are placed in the area of the breakdown of the water films. A mechanical obstacle (16) can be inserted behind the nozzle system (1) in the direction of gas flow.

Description

(57) Annotation:

The method for removing solids from gases is that the gas flows against at least one system of a plurality of water membranes arranged in a plane transverse to the direction of gas flow, wherein between the individual water membranes formed by the spraying of a jet of water of 0.5 to 30 m / s fed to the discs, gaps for gas passage are formed at a distance from the disc where the membranes disintegrate. The apparatus for carrying out the method consists of a gas flow pipe (4) in which at least one system of a plurality of nozzles (1) is disposed in one cross-sectional plane of the pipe (4), the nozzles (1) are provided with water. is 2 to 50 mm, a cylindrical disc (2) with a diameter of 1.2 to 5 d is placed against each nozzle, the impact surface (5) being flat or concave, the radius of the spherical concave surface (5) of the target (2) being larger as the diameter of the target (2) and the distance of the target from the nozzle orifice is greater than 1 mm and the nozzle orifice (1) is downstream or upstream. The nozzles (1) are located on the manifold (3) and the discs (2) are located opposite the nozzle orifices (1) on a beam (14) which is connected to the manifold (3) by supports (15) located in the region. disintegration of water membranes. A mechanical obstruction (16) may be inserted downstream of the nozzle system (1) in the gas flow direction.

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A method for removing particulates from gases and an apparatus for carrying out this method

Technical field

The invention relates to a method for removing solid particles from gases and to an apparatus for carrying out the method.

BACKGROUND OF THE INVENTION

The particulate gas impurities are removed by means of dynamic separators such as cyclones, electrostatic dedusters or septum filters, bag or cassette filters. More preferably, the method is to conduct the gas through finely divided liquid droplets or along a surface upon which liquid flows. Often, liquid is supplied to the wash towers at several levels (US 4164399), usually perpendicular to the gas direction, generally flowing from the bottom upwards. The gas is contaminated with liquid.

In US 4583999, the wash liquid is fed in the horizontal direction, but after some slowing of the horizontal movement of the droplets, they drop in the form of a fine shower.

In AO 25007 the air separator has a tangential air supply. In the center of the container are located central radial sprinklers, which form continuous liquid membranes and by reflection from the walls a liquid nebula that wets the surface particles.

According to DE 3341318 and US 3532595, the liquid is supplied at four to six levels. At each level there are several nozzles that spray the droplets in the form of conical screens. The apex angle of these conical screens is 90-120 °. The disadvantage of these devices is the large height in order to achieve a long rainfall of fine droplets. The necessary liquid must be pumped to a considerable height, which increases operating costs.

According to PV 2273-94, the spraying of the liquid takes place essentially in a plane perpendicular to the direction of gas flow. By alternating the arrangement of the stepping spray nozzles (180 ° apex angle) in individual planes, the gas flowing perpendicular to the liquid spray planes is forced to pulsate and the direct gas flow direction changes into a curve creating meanders around the nozzles located in the individual planes. The advantage is to extend the path of gas-liquid contact and increase the probability of collision of the particle with a drop of mist.

The device consists of an inlet mechanism for injecting finely divided liquid in the form of an umbrella-shaped or substantially linear orifice plate and according to PV 2273-94 is characterized in that the orthogonal orthogonal distance between adjacent planes with the inlet mechanism is so small as to prevent the gas flow between the planes, and the supply mechanism is located at the points where the gas concentration, respectively, occurs. higher gas velocity due to atomization of the liquid from the feed mechanism in the first plane.

Fine spraying of the liquid produces an aerosol in which the individual water spheres are well apart, and therefore dust particles pass easily therebetween. The atomized liquid has a particular effect on the cooling of the air, but dust retention is less effective in this process.

The idea of gas absorption and entrapment of solid particles from the gas into the fluid film was disclosed on September 15, 1922 in CS patent publication no. 9675th

It is an object of the present invention to absorb gas and entrap solid particles from the gas into the fluid film by forcing the gaseous substances within the enclosure to flow against two or more superimposed fluid surfaces moving by the fluid flow and interrupted at interleaved locations, that the gaseous substances entering through one or more interruptions of the lower liquid surface reach the gap between the two liquid surfaces, and entering one or more voids of the liquid surface lying above and flowing between the other liquid surfaces and their voids, they enter the space lying above all the areas from where they are discharged.

The apparatus for carrying out the method consists of a prismatic space in which two or more superimposed tubes with slotted openings are arranged parallel to the longitudinal or transverse walls, the empty spaces required for the passage of gas being formed by roof plates sitting on the shoulders. attached to the perimeter of the prismatic space.

It is apparent from the description and the claims that a single liquid membrane is formed over the entire cross-section of the tube through which the gas passes. In order to allow the gas to pass through, the membrane must be interrupted at some points near or near the wall of the tube.

In order to fill the entire cross-section of a pipe, one liquid membrane must be sufficiently thick to not disintegrate, especially for larger pipe diameters of several dcm to m. This solution is technically unrealistic because it would require considerable power of the electric motor of the pumps and a high water flow depending on the pipe size of several units up to 100 m ³ / hour. This compact membrane, which fills the entire cross-section of the pipe, must be rigid and rigid so that the flowing air does not interfere with its force effect. Conversely, the air flow is high resistance, which is not acceptable for fans and chimney draft. The resistance of the membrane system must be low so that air can flow freely without too sudden changes in the air flow, as any sudden change in air flow will cause a considerable loss of energy, so that the fans or chimney draft normally used would not overpress the required gas purge.

SUMMARY OF THE INVENTION

The disadvantages of the above are eliminated by the method of removing gaseous impurities and solid particles from gases trapped in a liquid membrane placed upstream of the gas in at least one plane according to the invention, which consists in that the gas flows against at least one system of several water membranes gasses, wherein gaps for gas passage are formed at a distance from the target where the membranes disintegrate between the individual membranes formed by spraying a jet of water at a speed of 0.5 to 30 m / s. The water containing the particles collected from the gas is returned to the process after treatment.

The apparatus for carrying out the method consists of a gas flow conduit in which at least one system of several nozzles is disposed in one plane of the cross-section of the conduit, the nozzles are provided with water inlet, nozzle diameter d is 2 to 50 mm. 1.2 to 5 d, the impact surface of which is flat or concave, the radius of the spherical concave surface of the target is greater than the diameter of the target and the distance of the target from the nozzle orifice is greater than 1 mm;

-4direction of gas flow. The nozzles can be arranged in alternation with the previous plane in individual planes. The nozzle system consists of a closed circuit with a collecting tank for effluent water containing solid particles from the gas, a circulation pump and a filter. The nozzles are located on the manifold and the targets are located opposite the nozzle orifices on a beam that is connected to the manifold by supports that are located in the area of disintegration of the membranes. The nozzles may be located on the manifold and the targets are calibrated with the nozzle, or the targets are connected to the nozzle body by a rod disposed within the nozzle. The nozzles can be placed around the circumference of the manifold in a spiral or row. A mechanical obstruction may be inserted downstream of the nozzle system in the direction of the gas flow, consisting of a screen, lattices, cords, bars, chains or plates on which solid particles are retained.

The method according to the invention creates a large contact surface of the membranes formed by the impact of the current on the targets, the air is forced to flow on the surface of the membranes and cannot pass straight in the direction of the pipeline axis without obstruction. When the solid particles come into contact with the surface of the membrane, the particle is wetted and drawn into the liquid film. After the membrane disintegrates, the liquid-encapsulated particle flows into the collection tank, eventually trapped on mechanical obstructions which are sprinkled with nozzle water. Barriers.

The nozzle system can be grouped in a plurality of planes in succession. In individual planes, they are preferably positioned alternately with respect to the previous plane so that the gas, when passing through the duct, cannot pass through the membrane system in a straight line. In addition, the individual nozzles around the circumference of the distribution pipe can be placed in a spiral or the distribution pipes with all the nozzles can be pivoted at the same time. This forces the air to flow in the desired directions, extends its path and increases the contact area with the membranes. This increases the likelihood of dirt coming into contact with the membranes. These impurities remain encapsulated in coarse droplets of the disintegrated membrane and flow into the collection tank. After filtration, the water from the recovery tank is used again to feed the nozzles. Water consumption is therefore very low. Only the loss of water resulting from evaporation and leakage of aerosol droplets entrained by the flowing air into the stack is added. The level in the collecting tank is replenished with clean water or from a sedimentation tank. The device according to the invention is very simple and reliable compared to the existing systems for separating solid impurities from gases. A sufficiently large nozzle diameter makes it possible to use recycled, already heavily contaminated water, while avoiding

-5plugging nozzles. The pressurized water flows from 0.1 to 0.2 MPa and therefore the whole plant is energy efficient.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 shows a wiring diagram of a dust extraction device.

Fig. 2 shows a front and side view of the nozzle design.

Fig. 3 shows another nozzle construction.

Fig. 4 shows the nozzle arrangement and its connection to the nozzle system.

DETAILED DESCRIPTION OF THE INVENTION

Example 1

36 nozzles 1 having a diameter of 6 mm were built into the 700 x 700 mm pipe 4. The water flow through one nozzle 1 was 227.8 l / h. (0.2278 m ³ / h), all nozzles 1 flowed 2.3 l / sec. (8.2 m ³ / hour). The flow rate was 2.24 m / sec. The clean air flow rate was 9,000 m ³ / h. and contained 230 mg impurities / m ³ .

After passing air through line 4, the impurity content varied around 13 to 23 mg / m ^J.

Example 2

24 nozzles I having a diameter d = 30 mm were incorporated into the 1 300 mm pipe 4. The water flow through one nozzle I was 5,695 m ³ / h. The flow rate was 2.20 m / sec. The clean air flow rate was 25,000 m ³ / h. and contained 250 mg impurities / m < -1 >.

After passing air through duct 4, the impurity content fluctuated around 25 mg / m ³ .

Example 3

The device shown in FIG. 1 consists of a pipe 4 in which a nozzle system I is installed. The nozzles I are arranged in three rows on the distribution pipes 3. A network mechanical obstruction 16 is arranged downstream of the nozzle system 16 in the gas flow direction. A target 2 is placed. The distribution pipes 3 are connected via a distribution block 7, circulating

-6 pump 8 and filter 9 with waste water collection tank 6. The collecting tank 6 is provided with a float 9 and a water flow 10 and a sludge pump 11

The air stream with impurities is forced to flow between the formed membranes. When the airborne dirt touches the water membrane, the dirt is sealed into the water and after the water membrane breaks down, the dirt enclosed in the water drop flows into the collection tank. Nozzle diameter is large enough - 10 cm and allows the circulation of polluted water.

Example 4

FIG. 2 shows a nozzle 1 with a target 2 attached to the nozzle 1 by a caliper 12. The surface 5 of the spot 2 is concave. A disadvantage of this nozzle 1 is the interruption of the membrane by the caliper 12. However, the diameter of the nozzle opening 1 can be very large.

Example 5

Figure 3 shows a nozzle with a target 2 which is connected to the nozzle 1 by a rod 13 located inside the nozzle 1. With this arrangement, the water membrane is not disturbed by anything, the possibility of clogging the nozzle 1 with impurities increases.

Example 6

Figure 4 shows the nozzles 1 placed on the manifold 3.

The targets 2 are located opposite the nozzle orifices on the beam 14, which is connected to the distribution pipe 3 by struts 15, which are located in the region of the disintegration of the membranes. This arrangement does not interfere with the formation of the membranes at all.

Industrial usability

The invention can be used to remove solid impurities from the gas stream.

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Claims (11)

A method for removing solid particles from gases trapped in a liquid film positioned upstream of a gas in at least one plane, characterized in that the gas flows against at least one system of several water membranes located in one plane transverse to the gas flow direction, by spraying a jet of water at a velocity of 0.5 to 30 m / s fed to the targets, gaps for gas passage are formed at a distance from the target where the membranes disintegrate. Method according to claim 1, characterized in that the water containing the particles retained from the gas is returned to the process after treatment. Apparatus for carrying out the method according to claim 1 and 2, characterized in that it consists of a gas flow pipe (4) in which at least one system of several nozzles (1) is disposed in one cross-sectional plane of the pipe (4), the nozzle (1). ) are provided with a water inlet, the diameter of the nozzles (1) d being 2 to 50 mm, a cylindrical target (2) having a diameter of 1,2 to 5 d, whose impact surface (5) is flat or concave, opposite each nozzle, the spherical concave surface (5) of the target (2) is larger than the diameter of the target (2) and the distance of the target from the nozzle orifice is greater than 1 mm and the nozzle orifice 1 is downstream or upstream. Apparatus according to claim 3, characterized in that it consists of a system of spaced nozzles (1) arranged in more than one cross-sectional plane of the air duct (4) in one cross-sectional plane, the nozzles (1) being arranged alternately in the individual planes. compared to the previous plane. Device according to claim 3, characterized in that the nozzle systems (1) form a closed circuit with a collecting tank (1). 6) for effluent containing solids from the gas, a circulation pump (8) and a filter (9). -86. Apparatus according to claim 3 and 4, characterized in that the nozzles (1) are arranged on the distribution pipe (3) and the targets (2) are placed opposite the orifices of the nozzles (1) on a beam (14) connected to the distribution pipe (3). ) by supports (15) which are located in the area of disintegration of the membranes. Device according to claim 3 and 4, characterized in that the nozzles (1) are arranged on the distribution pipe (3) and the targets (2) are connected to the nozzle (1) by means of the caliper (12). Device according to claim 3 and 4, characterized in that the nozzles (1) are arranged on the distribution pipe (3) and the targets (2) are connected to the nozzle body (1) by a rod (13) housed inside the nozzle (1). Device according to one of Claims 1 to 7, characterized in that the nozzles (1) are arranged in a spiral around the circumference of the distribution pipe (3). Device according to claim 1 to 7, characterized in that the nozzles (1) are arranged in a row around the circumference of the distribution pipe. Apparatus according to claims 1 to 10, characterized in that a mechanical obstacle (16) formed by a screen, lattices, bars, chains or plates is inserted downstream of the nozzle system (1). γγ ~ ^r > 1 Fig. 1 Fig. 2