RU2663731C2 - Scrubber with moving nozzle - Google Patents

Abstract

FIELD: instrument making.SUBSTANCE: present invention relates to wet dust collection and can be used in chemical, textile, food, light and other industries for purification of gases. Scrubber with a moving nozzle contains a housing with nozzles for dusty and clean gas, an irrigation device, made in the form of a manifold with injectors, a lower support-distributing plate and an upper restricting plate, between which the nozzle layer is located, the splatter trap and the slurry removal device, the lower support and distribution and upper restricting plates and the nozzle are made of resilient materials, and a vibrator is mounted on the top and bottom trays, and each of the nozzles comprises a body that is hollow, axisymmetric, whose axis is perpendicular to the axis of the opening of the manifold pipe, but in form the body is made in the form of a body of revolution formed by a curve of the second order, for example spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and on the side of the flow opening of the manifold pipe, a rectifying element is provided in the nozzle, made in the form of a ring, having a central sleeve with which radially disposed at least three blades are rigidly connected, connected to the body of the injector, the body being provided with ledges with two oppositely arranged, perpendicular to the axis of the nozzle, by means of which, through the clamps with locks, the nozzle is fixed to the manifold, with a conical throttle opening connected to the mixing chamber in the lower part of the nozzle body, which is located between the throttle opening and the rectifying element, and on the inner surface of the mixing chamber there are screw-like grooves, or the nozzle is made in the form of a cylindrical ring, to side surface of which two opposite hemispherical surfaces are attached so, that hemispheres diametral planes match with cylindrical ring top and bottom bases, respectively, and the vertices of hemispherical surfaces are located on the axis of the ring and are directed towards each other, the nozzle element being perforated both on the lateral surface and on hemispherical surfaces, or the nozzle is made in a spherical shape, in which there are blind radial notches, the recesses being cylindrical, conical, spherical surfaces, or any surface of bodies of revolution, for example a paraboloid, an ellipsoid, or a nozzle made of a hollow spherical shape, on the outer surface of which there are additional elements in the form of spherical, conical surfaces, or any surface of the bodies of revolution, for example a paraboloid, an ellipsoid, and the inner spherical surface of the nozzle is connected to the outer by means of at least one three channels, or the nozzle is made in the form of a cylindrical ring, on the side, inner and outer, surfaces of which are screw-threaded in opposite directions, or the nozzle is made in the form of a ball on the surface of which blind holes of hemispherical shape are made.EFFECT: technical result is an increase in the efficiency and reliability of the dust collection process, as well as a decrease in the metal intensity and vibroacoustic activity of the device as a whole.1 cl, 10 dwg

Description

The invention relates to techniques for wet dust collection and can be used in chemical, textile, food, light and other industries for the purification of dusty gases.

The closest technical solution to the claimed object is a scrubber with a movable nozzle, known from RF patent No. 2280492 (prototype), comprising a housing with nozzles for dusty and purified gas, an irrigation device, a lower support and distribution plate and an upper restrictive plate, between which there is a layer nozzle, and device for removal of sludge.

The disadvantage of the prototype is the relatively low efficiency of the dust collection process due to the underdeveloped surface of the nozzle.

The technical result is an increase in the efficiency and reliability of the dust collection process, as well as a decrease in the metal consumption and vibroacoustic activity of the apparatus as a whole.

This is achieved by the fact that in a scrubber with a moving nozzle containing a housing with nozzles for dusty and purified gas, an irrigation device made in the form of a collector with nozzles, a lower support and distribution plate and an upper restrictive plate, between which there is a nozzle layer, a spray catcher and a device for the removal of sludge, the lower support and upper restrictive plates and the nozzle are made of elastic materials, and a vibrator is installed on the upper and lower plates, and each of the nozzles with will contain a body that is hollow, axisymmetric, whose axis is perpendicular to the axis of the hole of the manifold pipe, and the shape of the body is made in the form of a body of revolution formed by a second-order curve, for example spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and from the side of the flow hole of the manifold pipe a straightening element is installed in the nozzle, made in the form of a ring having a central sleeve with which at least three blades are radially spaced, connected to the unit, the housing is made with two opposite, perpendicular to the axis of the nozzle, ledges, through which through the clamps with locks the nozzle is fixed to the collector, while in the lower part of the nozzle body there is a conical throttle hole connected to the mixing chamber, which is located between the throttle hole and a straightening element, and on the inner surface of the mixing chamber there are helical grooves, the nozzle is made in the form of a cylindrical ring, to the side surface of which two hemispherical surfaces are affixed positively to each other so that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, respectively, and the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards each other.

In FIG. 1 shows a scrubber with a movable nozzle; FIG. 2 shows the shape of the nozzle; FIG. 3 is a nozzle diagram; FIG. 4 is a cross-section of a nozzle in the form of balls with recesses, in FIG. 5 is a cross-section of a nozzle in the form of balls with additional elements on the outer surface, in FIG. 6 is a variant of the nozzle in the form of hemispherical surfaces, in FIG. 7-10 - nozzle options.

A scrubber with a moving nozzle comprises a housing 1 with nozzles 2 and 3, respectively, for dusty and purified gas (air), an irrigation device containing a collector 7 with nozzles 9, a lower support and distribution plate 4 and an upper restrictive plate 6, between which there is a layer of nozzle 5 , a spray catcher and a device for removing sludge 8 (Fig. 1). The lower 4 supporting distribution and upper 6 restrictive plates and nozzle 5 are made of elastic materials. A vibrator (not shown) can be installed on the lower support-distribution plate 4. On the upper restrictive plate 6 can be installed a vibrator (not shown). On the lower 4 supporting distribution and upper 6 restrictive plates can be installed on a vibrator (not shown).

The spray catcher is made in the form of concentric cylindrical rings 1 ... 2 mm thick, and with a distance between them 3 ... 4 mm. The spray catcher is made in the form of concentrically arranged rings having, in cross section passing through the axis of the ring, a zigzag profile, for example a sinusoidal one, moreover, the thickness of the rings is 1 ... 2 mm, and the distance between them is 3 ... 4 mm. The spray catcher is made in the form of concentrically arranged rings having a section in the section passing through the axis of the ring, a profile consisting of series-connected circles, with the rings having a maximum thickness of 3 ... 4 mm and a distance between them of 4 ... 5 mm (not shown in the drawing) .

In order to increase the degree of purification of the gas stream from dust or the target component by increasing the contact area of the dusty stream with the nozzle 5 (Fig. 2), the nozzle element is made in the form of a cylindrical ring, to which two hemispherical surfaces 11 are attached opposite to each other, thus that the diametrical planes of the hemispheres coincide with the upper 12 and lower bases of the cylindrical ring, respectively, and the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards each other Yeah.

It is possible to perform nozzles with perforation 13 both on the side surface 10 and on hemispherical surfaces 11.

The nozzle 5 can be made of porous polymeric materials, glass, porous rubber, composite materials, wood, stainless steel, titanium alloys, precious metals.

The nozzle 9 for spraying liquid (absorbent) is located on the manifold 7 having a flow hole 14. Each of the nozzles (Fig. 3) is made in the form of a hollow, axisymmetric body 15, the axis of which is perpendicular to the axis of the collector 7, and the body is made in the form of a body a rotation formed by a second-order curve, for example spherical, in the form of a truncated ellipsoid or paraboloid of rotation, etc. On the side of the flowing hole 14 of the pipeline, a straightening element 19 is installed in the nozzle, which dampens the turbulence of the fluid flow STI coming from the pipe to the nozzle. The straightening element is made in the form of a ring having a central sleeve 19, with which at least three vanes 20 are radially arranged and connected to the nozzle body 15. The housing 15 is made with two opposite steps, perpendicular to the axis of the nozzle, ledges 18, through which through the clamps 16 with locks 17 the nozzle is fixed to the manifold 7. In the lower part of the housing 15 of the nozzle there is a tapered calibrated throttle hole 22 connected to the mixing chamber 21, which located between the hole 22 and the straightening element. The mixing chamber 21 is intended to form a vortex turbulent flow formed at the outlet of the nozzle opening 22. For this purpose, there are helical grooves (not shown in the drawing) on the inner surface of the mixing chamber, which can be formed by turning by copying, or obtained by injection molding. As a result of this, a finely dispersed and uniform jet of liquid is formed at the outlet of the nozzle.

The nozzle may be made of balls, i.e. it is spherical in shape (Fig. 4), in which non-through radial recesses are made, the recesses having the form of cylindrical, conical, spherical surfaces, or any surface of bodies of revolution, for example, a paraboloid, an ellipsoid.

The nozzle can be made hollow spherical in shape (Fig. 5), on the outer surface of which there are additional elements in the form of spherical, conical surfaces, or any surface of bodies of revolution, for example, a paraboloid, an ellipsoid, and the inner spherical surface of the nozzle is connected to the outer by at least at least three channels.

To increase the degree of purification of the gas stream from dust or the target component by increasing the contact area of the dusty stream with the nozzle 5 (Fig. 6), the nozzle element is made in the form of at least three, coaxially located hemispherical surfaces 23, 24, 25 connected between each other with a gap by means of a fastening element, for example in the form of a bolt 26 with a nut 27, through axisymmetrically located, mounting elements 28 and 29, for example in the form of rings. Between the hemispherical surfaces 23, 24, 25 corrugated elements 30 and 31 are fixed on the mounting elements, having the form of a forming surface that is equidistant to hemispherical surfaces. Corrugated elements 30 and 31 can be made perforated (not shown). Hemispherical surfaces of the nozzle element may be perforated.

The mounting elements 28 and 29 can be made in the form of coil springs (not shown in the drawing).

A variant is possible when the nozzle is made of a lattice structure (Figs. 7 and 8) inscribed in a circle and consisting of at least two supporting plates located along the chords of the circle, close to its diameter, which are perpendicular to at least twelve additional plates parallel to each other, made in the parallel direction of the chords of a circle, with a uniform distribution along its diameter.

A variant is possible when the nozzle is made in the form of a cylindrical ring and lattice structure, which are made with perforation on the surfaces forming them.

A variant is possible when the nozzle is made in the form of a cylindrical ring on the lateral, inner and outer surfaces of which a screw thread is made (not shown in the drawing) in opposite directions (Fig. 9).

A variant is possible when the nozzle is made in the form of a ball, on the surface of which non-through holes are made hemispherical in shape (Fig. 10).

A scrubber with a moving nozzle works as follows.

The dusty gas stream enters the housing 1, through the inlet of the dusty gas stream 2, and meets a curtain from the nozzle 5, which is wetted with water or other absorbent from the irrigation device, made in the form of a collector 7 with nozzles 9. To remove the sludge, device 8 is used to remove sludge in the form of a channel in the bottom of the housing or a separate mechanism. To ensure free movement of the nozzle 5 in the gas-liquid mixture, its density should not exceed the density of the liquid. The process of dust collection takes place in the optimal hydrodynamic mode of the gas scrubber, characterized by the regime of full developed fluidization. To intensify the hydrodynamic regime, a vibrator (not shown in the drawing) can be installed on the lower support distribution plate 4, or a vibrator (not shown in the drawing) can be installed on the upper restriction plate 6, or simultaneously on the lower 4 distribution and upper limit 6 plates can be installed on a vibrator (not shown in the drawing). This will allow the scrubber to switch to the vibro-fluidized bed mode, in which the interaction efficiency of the nozzle 5, irrigated by the liquid, with the gas phase will increase, and, consequently, will increase the overall efficiency of the apparatus. The implementation of the nozzle 5, the lower 4 of the support distribution and upper 6 restrictive plates of elastic material will allow under certain conditions to create a mode of oscillation or self-oscillations, which will also increase the efficiency of interaction of the nozzle 5 with the irrigated liquid. Moreover, to reduce the vibro-acoustic activity of the apparatus and its metal consumption, as well as to increase its reliability, the proposed device provides the following measures: a layer of soft vibration-damping material, for example, VD-17 mastic (not shown), is applied to the surface of the parts, and the ratio between the metal thickness and vibration-damping coating is in the optimal range of values: 1 / (2.5 ... 4).

The nozzle 9 of the irrigation device operates as follows.

Liquid under pressure enters from the nozzle inlet 14 of the manifold 7 into the nozzle and encounters a straightening element 19 in its path, which dampens the turbulence of the fluid flow from the manifold to the nozzle. The mixing chamber 21 is intended for the formation of a vortex turbulent flow formed at the outlet of the nozzle orifice 22, as a result of which a finely dispersed and uniform liquid spray is formed at the nozzle exit. The nozzle is easy to manufacture and maintain.

The scrubber can be used to clean fine dust and humidify air in ventilation units and air conditioning units, as well as in trapping mists, readily soluble dust, as well as in the process of dust collection, gas cooling and absorption of packed gas washers. The effectiveness of the proposed design of the nozzle scrubber increases due to the larger interaction surface of the nozzle in the above processes, as well as optimization of the hydrodynamic situation, and amounts to about 97% when collecting dust particles larger than 2 microns in size.

Claims (1)

A scrubber with a moving nozzle, comprising a housing with nozzles for dusty and purified gas, an irrigation device made in the form of a manifold with nozzles, a lower support and distribution plate and an upper restrictive plate, between which there is a nozzle layer, a spray catcher and a device for removing sludge, a lower support - the distribution and upper restrictive plates and nozzle are made of elastic materials, and a vibrator is installed on the upper and lower plates, and each of the nozzles contains a housing that is hollow, axisymmetric, the axis of which is perpendicular to the axis of the hole of the manifold pipe, and the body is made in the form of a body of revolution formed by a second-order curve, for example spherical, in the form of a truncated ellipsoid or paraboloid of revolution, and a straightener is installed on the side of the flow hole of the manifold pipe an element made in the form of a ring having a central sleeve with which at least three blades radially arranged are connected rigidly and connected to the nozzle body, the body being made n with two opposite steps, perpendicular to the axis of the nozzle, ledges, through which through the clamps with locks the nozzle is fixed to the manifold, while in the lower part of the nozzle body there is a conical throttle hole connected to the mixing chamber, which is located between the throttle hole and the straightening element, and on the inner surface of the mixing chamber there are helical grooves, or the nozzle is made in the form of a cylindrical ring, to the side of which is oppositely attached to each other Two hemispherical surfaces are bonded so that the diametrical planes of the hemispheres coincide with the upper and lower bases of the cylindrical ring, respectively, and the vertices of the hemispherical surfaces are on the axis of the ring and are directed towards each other, while the nozzle element is made with perforation both on the side surface and on hemispherical surfaces, or the nozzle is made spherical in shape, in which there are non-through radial recesses, and the recesses are in the form of a cylindrical, conical, spherical of surfaces, or any surface of bodies of revolution, for example a paraboloid, an ellipsoid, or a nozzle is made hollow spherical in shape, on the outer surface of which there are additional elements in the form of spherical, conical surfaces, or any surface of bodies of revolution, for example a paraboloid, an ellipsoid, and the inner spherical surface the nozzle is connected to the outer by at least three channels, or the nozzle is made in the form of a cylindrical ring on the side, inner and outer, the surfaces of which are made in ntovaya cutting in opposite directions, or nozzle is formed as a ball, the surface of which non-through holes formed hemispherical shape.

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