RU2325941C1 - Vortex dust collector with liquid acoustic sprayer - Google Patents

Abstract

FIELD: mechanics; filtration.

SUBSTANCE: invention relates to devices designed to scrub gas of dust and may be used in pneumatic transport systems, pneumatic cleaning, aspiration. The vortex dust collector has a cylinder case, a dusted gas axial inlet with a swirler, an ejector nozzle, a fairing and a tapered deflector ring. The case upper part accommodates an axial branch pipe to force out a cleaned gas and a periphery secondary flow inlet with the swirler. The dusted gas axial inlet, and the periphery secondary flow inlet accommodate acoustic jets to feed spraying water. The jet has a case with a cup and central core arranged inside it and forming an acoustic oscillation generator, a tapered surface ring coupled to the case and a sprayer. The resonator is made as, at least one spherical space arranged in the central core body, the spherical space being connected via a gauged orifice with a circular slot formed by the cup face surfaces and those of the central core. The central core is arranged so that a fixed motion is allowed along the case axis by means of threaded joint fixed by lock nuts. The proposed invention allows the dust collection higher efficiency.

EFFECT: higher efficiency of dust collection.

2 cl, 2 dwg

Description

The invention relates to techniques for cleaning gas from dust and can be used in various industries in pneumatic conveying systems, pneumatic cleaning, aspiration.

The closest technical solution to the claimed object is a vortex dust collector according to RU No. 2256487, class. B04C 3/06, comprising a housing, an axial inlet of dusty gas with a swirl and a fairing and a baffle plate, as well as an axial nozzle for discharging purified gas and a peripheral inlet of the secondary stream with a swirl located in the upper part of the housing, the housing is cylindrical and the baffle is conical, wherein the ejection nozzle forms an annular channel with the input wall formed by the conical surfaces of the axial input and the ejection nozzle, respectively, while the cut plane of the ejection nozzle is located above the plane STI cut conical baffle washer.

The disadvantage of the prototype is the relatively low efficiency of dust collection due to the fact that dry dust collection does not contribute to the coagulation of fine particles.

The technical result is an increase in the efficiency of dust collection.

This is achieved by the fact that in the vortex dust collector containing the housing, the axial inlet of dusty gas with a swirl and an ejection nozzle, a cowl and a breaker washer, as well as an axial nozzle located in the upper part of the housing for outputting purified gas and a peripheral inlet of the secondary stream with a swirl, the housing is made cylindrical, and the baffle plate is conical, while the ejection nozzles form an annular channel with the input wall, formed by the conical surfaces of the axial input and the ejection nozzle, respectively, with Volume of the cut-off plane of the ejection nozzle is located above the cut-off plane of the conical baffle plate, in the lower nozzle of the axial inlet of dusty gas with a swirl, a cowl and a breaker, as well as in the upper nozzle of the peripheral inlet of the secondary flow with a swirler, acoustic nozzles for irrigation fluid supply are installed, each of which consists of a housing with a glass placed inside and a shaft with a conical shoulder forming an acoustic oscillation generator, consisting of a nozzle in the form of an annular gap and a reason ora, a ring with a conical surface associated with the housing, and a spray gun made in the form of an annular cavity bounded by a cylindrical sleeve in which the fluid supply openings are evenly arranged, the resonator being made in the form of at least one spherical cavity located in the body a central rod coaxially located in the glass, coaxial to the housing, the spherical cavity being connected by a calibrated hole to an annular gap formed by the end planes of the glass and the central rod with one the flanges of the conical surface of the shoulder, and the central rod is located with the possibility of fixed movement along the axis of the housing by means of a threaded connection fixed by locknuts.

Figure 1 presents a vortex dust collector, General view; figure 2 - acoustic nozzle.

The vortex dust collector (Fig. 1) contains a cylindrical body 1 with a hopper 2, an axial inlet 3 with a swirl 4, a cowl 5, a baffle plate 6 and an ejection nozzle 7, an inlet 8 of the secondary flow with a swirl 9, and an axial nozzle 10 for removing purified gas. The ejection nozzles 7 form an annular channel with the input wall 3, communicating with the body cavity under the baffle plate 6, which can be made dish-shaped, conical or flat (not shown in the drawing), and the annular channel of the ejection nozzle can be formed by cylindrical or conical surfaces, respectively, axial input 3 and the ejection nozzle 7, while the cut plane of the ejection nozzle may be lower than the cut plane of the conical washer.

In the axial inlet 3 of dusty gas with a swirl 4, a cowl and a breaker washer, as well as in the inlet 8 of the secondary stream with a swirl 9, acoustic nozzles 11 are installed with nozzles for supplying liquid 12 and compressed gas 13 (Fig. 2) for supplying irrigation liquid, each one of them contains a housing 14 with a cup 25 placed inside and a central shaft 23 with a conical shoulder 24 forming an acoustic oscillator in the form of a nozzle made in the form of an annular gap 17 and a resonator. The ring 19 is made with a conical surface 20, connected with the housing 14, and the sprayer is made in the form of an annular cavity 16 bounded by a cylindrical sleeve with a platform 22, in which the holes 21 for supplying liquid are uniformly located. The resonator is made in the form of at least one spherical cavity 28 located in the body of the central rod 23, coaxially located in the glass 25, coaxial housing 14, and the spherical cavity 28 is connected by a calibrated hole 29 with an annular gap 18 formed by the end planes of the glass and the central rod from the side of the conical surface of the shoulder 24, and the Central rod is located with the possibility of fixed movement along the axis of the housing 14 by means of a threaded connection fixed by locknuts 30.

The resonator can be configured to control the generated frequency of acoustic vibrations by adjusting the width of the annular gap 18 formed by the end planes 26 of the cup 25 and the central rod 23 from the side of the conical surface of the flange 24, by installing between the bottom of the cup 25 and the end of the rod 23 from the opposite side the conical surface of the shoulder 24, calibrated gaskets 29, the thickness of which corresponds to a given frequency of acoustic vibrations.

Vortex dust collector operates as follows. The dust and gas stream enters through the inlet 8 of the secondary stream and, spinning with a scapular swirler 9, moves downward in the housing 1. A dusty primary gas is supplied towards it from below through the axial inlet 3, which is swirled by the axial-scapular swirler 4 in the same direction as the descending secondary stream . In this case, dust particles are thrown to the walls of the housing under the action of centrifugal forces 1. The swirling secondary stream, encountering the baffle plate 6, partially unfolds, interacting with the primary stream coming from the central inlet 3. Dust particles with greater inertia are separated from the stream when it turning at the baffle plate 6 and through the gap between it and the walls of the housing 1 fly into the hopper 2. In the hopper 2 creates a vacuum due to the ejection nozzle 7 installed in the axial inlet 3 close to the swirl 4. Suction an ejector, a stream that can contain the smallest dust particles, especially with a small specific gravity and a size of less than 10 microns (light solid particles), flows directly to the blades of the swirler 4, and at the maximum radius, which ensures their maximum swirling and removal from the periphery of the gas stream into the secondary stream and then back to hopper 2. This contributes to the optimal interaction of the swirling stream of the primary stream with the downward flow of the swirling secondary stream and to increase the efficiency of dust collection by returning to the bun ker dust particles with a low specific gravity.

The acoustic nozzle for spraying liquids works as follows. A spraying agent, for example air, is supplied through a gas channel 15, where it meets a resonator 28 in its path, made in the form of a spherical cavity connected to the nozzle 17 through a calibrated hole 29. As a result of the passage of the resonator 28, a spraying agent (for example, air) in the latter pressure pulsations creating acoustic vibrations, the frequency of which depends on the parameters of the resonator. The acoustic vibrations of the spraying agent contribute to a finer atomization of the solution supplied to the channel 16, from which the liquid flows in the form of a film to the platform 22, and then crushes under the influence of acoustic vibrations of air into small drops, resulting in the formation of a spray torch with air, the root angle which is determined by the angle of inclination of the conical surface 20 of the ring 19.

Thus, the execution of the apparatus body is cylindrical and the presence of an ejector installed in an axial gas pipeline allows for high separation efficiency of small particles with a low specific gravity and can be used for dust cleaning in various industries. The proposed device is reliable in operation and operation by simplifying the design of the ejector.

Claims (2)

1. A vortex dust collector with acoustic liquid atomization, comprising a cylindrical body, an axial inlet of dusty gas with a swirl and an ejection nozzle, a cowl and a breaker washer, as well as an axial nozzle for discharging purified gas and a peripheral inlet of the secondary stream with a swirl, located in the upper part of the housing made cylindrical, and the baffle plate is conical, while the ejection nozzles form an annular channel with the input wall formed by conical surfaces corresponding to the axial input and an ejection nozzle, wherein the cut-off plane of the ejection nozzle is located above the cut-off plane of the conical baffle plate, characterized in that in the lower nozzle of the axial inlet of dusty gas with a swirl, a fairing and a breaker, and also in the upper nozzle of the peripheral inlet of the secondary stream with a swirl nozzles for supplying irrigation liquid, each of the nozzles consisting of a housing with a cup placed inside the cup and a central shaft with a conical shoulder forming a generator oscillatory oscillations, consisting of a nozzle in the form of an annular gap and a resonator, a ring with a conical surface connected to the body, and a spray gun made in the form of an annular cavity bounded by a cylindrical sleeve in which the holes for supplying liquid are uniformly arranged, the resonator being made in the form of at least one spherical cavity located in the body of the Central rod, which is connected by a calibrated hole to the annular gap formed by the end planes of the glass and the Central rod with side of the conical surface of the shoulder, and the Central rod is located with the possibility of fixed movement along the axis of the housing by means of a threaded connection fixed by locknuts. 2. The vortex dust collector with acoustic liquid spraying according to claim 1, characterized in that the nozzle resonator is configured to control the generated frequency of acoustic vibrations by adjusting the width of the annular gap formed by the end planes of the glass and the central rod from the side of the conical surface of the flange, by installing between the bottom of the glass and the end plane of the central rod from the side opposite the conical surface of the shoulder, calibrated gaskets, the thickness of which sponds to a given frequency of the acoustic vibrations.

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