RU2371257C1 - Ultrasonic sprayer of liquid - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention is related to devices for spraying of liquids, in particular water and aqueous solutions used in extinguishing of fires in closed rooms, may be used for a whole range of production processes. Technical result is achieved by the fact that nozzle is made in the form of deflector shaped as axisymmetric figure with cylindrical side surface and internal hollow truncated cone. Nozzle deflector is installed in body coaxially to central gas flue and is inverted with a large base of hollow truncated cone opposite to central gas flue with creation of nozzle slot. Height of resonator groove and width of nozzle slot are selected provided that 1.7≤σ/δ≤2.2. Sprayer is also equipped with an annular resonator with cut edge in the form of conical surface. Annular resonator is installed on bearing part of body with creation of grooves relative to upper part of resonator. Upper part of body is arranged with a cone-shaped funnel coupled with cut edge of resonator.

EFFECT: increased efficiency, higher intensity of impact waves and reduction of size of produced finely dispersed liquid drops.

4 cl, 4 dwg

Description

The invention relates to a device for spraying liquids, in particular water and aqueous solutions used in extinguishing fires in enclosed spaces, can also be applied to a number of production processes, for example, in the metallurgical industry during cooling of rolled products; in agriculture with humidification of air in greenhouses and with foliar feeding of plants, as well as for vaccination of animals; in medicine during the disinfection of rooms and a number of other cases.

Pneumatic-acoustic nozzles are known in which atomization is carried out by a gas jet, part of the energy of which is converted into acoustic vibrations by the principle of a Hartmann generator by braking a supersonic jet by a hollow resonator. Bergman L. Ultrasound and its application in science and technology, trans. with it., 2nd ed., M., 1957.

Known nozzles in which receive a flat wall fan stream. Yu.Ya. Borisov. "Design features of gas-jet emitters." Acoustic magazine. 1980 v. 26, No. 1.

In these nozzles, the spraying and generating acoustic vibrations gas is supplied through a central hole in the housing to a deflector that changes the direction of gas movement from axial to perpendicular. In this case, a fan stream arises, which is inhibited by a ring resonator located on the periphery. The sprayed liquid is supplied through the central rack, on which the deflector is mounted. USSR copyright certificates “Nozzle for spraying liquids”, No. 306270, B05B 17/06, 1970 and “Acoustic sprayer”, No. 328945, B05B 17/06. 1970.

The sprayed liquid can also be supplied directly to the generation zone through the housing, crossing the gas stream, or outside the resonator. "Acoustic nozzle". U.S. Patent No. 3,779,460, B05B 17/06. 1973.

When designing disc nozzles with a diverging stream, the peculiarities of the appearance of generation in fan jets were not taken into account.

Divergent disc nozzles were ineffective and did not find practical application. D.G. Pazhi, B.C. Galustov. Fundamentals of spraying liquids. M. Chemistry, 1984.

Known ultrasonic liquid atomizer containing a cylindrical body with a Central hole, in which a Central rod with an inlet gas channel is installed. The housing has a fluid inlet, a fluid annular chamber, a fluid nozzle, and a gas nozzle. A resonator is mounted on the protruding part of the central shaft. In the central rod there are gas passages connecting the gas inlet to the gas chamber, the liquid inlet is located at the periphery of the end face of the cylindrical body and extends axially. The liquid nozzle is made in the form of fluid passage channels in a cylindrical housing connected with a liquid annular chamber. Patent of the Russian Federation No. 2232647, IPC: B05B 17/04, 2004.

Known ultrasonic atomizer for liquids, containing a composite housing with a central gas duct, nozzle, resonator and deflector, channels for supplying liquid and gas. An annular groove is made on the inner surface of the cylindrical sleeve of the spray gun, communicating with at least one radial channel of the deflector. Patent of the Russian Federation No. 2088343, IPC: B05B 17/06, 1997. Prototype.

Like analogues, the device has low performance and low intensity.

This invention eliminates the disadvantages of analogues and prototype.

The objective of the invention is the development of an ultrasonic liquid atomizer of increased productivity and intensity of shock waves, increasing the dispersion of drops of the working fluid.

The technical result of the invention is to increase productivity, increase the intensity of shock waves and reduce the size of the obtained fine liquid droplets.

The technical result is achieved by the fact that in an ultrasonic liquid atomizer containing a composite housing with a central gas duct, a nozzle, a resonator and a deflector, channels for supplying liquid and gas, the nozzle is made in the form of a deflector in the form of an axisymmetric figure with a cylindrical side surface and with an internal hollow truncated cone , the deflector is installed in the housing coaxially with the central gas duct and faces with a large base of a hollow truncated cone towards the central gas duct with the formation of a nozzle gap, the height of the groove the zoning and the width of the nozzle slit are selected from the condition:

1.7 <σ / δ≤2.2,

where σ is the height of the cavity of the resonator, δ is the width of the nozzle gap, the nozzle is equipped with a ring resonator with a depth h with a cut edge in the form of a conical surface, the ring resonator is mounted on the bearing part of the body with the formation of grooves relative to the upper part of the resonator, the upper part of the body is made with a conical funnel, conjugated to the cut edge of the resonator. The nozzle deflector is installed in the housing with the possibility of axial movement coaxially with the central gas duct. The diameter of the nozzle deflector is selected from the condition: d _c / λ = 1.09 · 1.3 ⁿ , where d _c is the diameter of the nozzle deflector, λ is the wavelength of the excited oscillations, n = 0; one; 2; 3 ...

The ultrasonic liquid atomizer is equipped with a set of ring resonators of different diameters with elements for their rigid fixation on the bearing part of the body.

The invention is illustrated by drawings.

Figure 1 schematically shows a variant of an ultrasonic liquid atomizer with a nozzle baffle mounted on the central rod, where: 1 - the bearing part of the body, 2 - the upper part of the body, 3 - nozzle baffle, 4 - the central rod, 5 - ring resonator, 6 - input liquids, 7 — grooves, h — cavity depth, σ — cavity groove height, δ — nozzle gap width, d _c — nozzle deflector diameter, d _p — resonator cut-off diameter.

Figure 2 presents the characteristics of the change in the efficiency of the atomizer from the ratio d _c / λ, - the diameter of the nozzle deflector to the wavelength of the excited oscillations at different values of the diameter of the nozzle deflector.

Figure 3 presents the dependence of sound pressure on the ratio of the height of the cavity grooves to the width of the nozzle slit.

Figure 4 schematically shows a variant of the ultrasonic liquid atomizer with the nozzle baffle mounted on the console.

To understand the essence of the invention, we consider the principle diagram of the Hartmann generator. Regardless of the shape of the nozzle used (Hartmann has a round one), when the latter is supplied with gas with a pressure P above the critical P _cr

P _cr / P _a = [(γ + l) / 2] ^{γ / (γ-1)} ,

where P _a is the pressure in the environment, and γ is the adiabatic coefficient, the value of which depends on the nature of the gas supplied to the nozzle, at the nozzle exit the Mach number becomes equal to unity, and the jet acquires a barrel-shaped structure with supersonic and subsonic regions. At the same time, if the length of each barrel remains unchanged in cylindrical jets, then in the fan stream, due to flow divergence as the distance from the nozzle increases, the length of each subsequent barrel is reduced, and therefore work in the disk radiator is carried out in the first barrel.

When such a jet is braked by an obstacle, in particular, a hollow cylindrical resonator 5, an unstable outflow regime and the appearance of periodic shock waves, which are used in atomizers to crush the liquid, are possible. However, generation occurs only when the resonator is located in the instability zone located between the end of the barrel and the position of the minimum static pressure in the free stream (at the end of the barrel, the gas-dynamic parameters that existed at the nozzle exit are usually restored, but the situation in the fan stream changes slightly due to its divergence )

According to modern concepts, in the Hartmann generator there are two feedback loops responsible for the occurrence of instability. One of them, the internal one, determines the generation frequency and lies in the subsonic zone of the barrel between the plane jump that appeared during jet braking and the bottom of the resonator. This is a kind of quarter-wave resonator having one rigid wall (bottom) and one soft (flat jump). The second, external loop, carried out outside the jet, acts between the edge of the cylindrical resonator 5 and the cut of the nozzle deflector 3, practically without affecting the frequency, it can either enhance or weaken the intensity of the oscillations.

In a flat diverging jet, due to the specificity of its structure, the external feedback loop has a significant effect on the generation, which was not taken into account in the previously proposed designs.

We found that, depending on the distance between the nozzle baffle 3 and the ring resonator 5, on the one hand, and the wavelength of acoustic vibrations, on the other, there is a rigid dependence that determines the positive or negative effect of the influence of the external feedback loop, which can even lead to disruption of generation.

The gas flow rate in a disk-type atomizer depends on the pressure P and the area of the nozzle outlet S = πd _c δ, where d _c is the diameter of the nozzle baffle (Fig. 1), and δ is the width of the nozzle gap, which determines the length Δ of the resulting barrel:

.Here G = δ / d _c is the jet curvature (divergence) parameter, the quantity

.

Thus, for an atomizer with a required atomizing gas flow rate and, accordingly, a nozzle baffle diameter d _c, there is an optimal wavelength at which generation and atomization will be effective.

As a result of studies conducted with nozzle baffles of various sizes (d _c = 15 ... 40 mm; δ = 0.4 ... 1 mm) that overlap the real range of estimated air flow rates for the nozzle Q = 1 ... 10 kg / min (at pressures 0, 25-0.50 MPa), it was found that the optimal generation is observed (Fig. 3) with the ratio: d _c / λ = 1.09 · 1.3 ⁿ , where n = 0, 1, 2, ...

Satisfactory operation of the atomizer is maintained when the frequency changes within ± 5% and the pressure changes within ± 20%, which is actually achievable using modern pressure reducers and pressure regulators, and these modes are achievable with atomizer element sizes satisfying the condition: 1.7≤σ / δ≤2,2, where σ is the height of the cavity of the resonator, δ is the width of the nozzle gap.

Ultrasonic liquid atomizer operates as follows. When applying to the body of the atomizer 1 (Fig. 1) working gas, the latter through a central hole enters the nozzle deflector 3, which serves simultaneously as a nozzle of a gas-jet generator. The nozzle deflector 3 can be mounted either to a central shaft 4 mounted in the central hole or to an external console (FIG. 4).

The gas flow through the annular nozzle gap in the form of a fan stream enters the annular resonator 5, the depth of which h and the height σ specify, at the selected pressure P, the required oscillation frequency.

The jet acquires a pulsating character, which leads to the generation of periodic shock waves emitted into the surrounding space, where it splits a thin film of liquid entering the spray zone through grooves 7.

The possibility of changing the axial displacement of the nozzle deflector coaxially with the central gas duct allows you to tune to the frequency at which for this spraying gas the wavelength of the oscillations λ associated with the diameter of the nozzle deflector d _{with the} ratio d _c / λ = 1.09 · 1.3 ⁿ , where n = 0, 1, 2, 3, ...

A set of ring resonators of different diameters with elements for their rigid fixation on the bearing part of the housing allows you to start the ultrasonic liquid atomizer in the modes determined by the diameter of the resonator.

Claims (4)

1. An ultrasonic liquid atomizer comprising a composite body with a central gas duct, a nozzle, a resonator and a deflector, channels for supplying liquid and gas, characterized in that the nozzle is made in the form of a deflector in the form of an axisymmetric figure with a cylindrical lateral surface and with an internal hollow truncated cone, the nozzle deflector is installed in the housing coaxially with the central gas duct and faces with a large base of a hollow truncated cone towards the central gas duct with the formation of a nozzle gap, the height of the cavity of the resonator and w Rina nozzle holes are chosen from the condition:
1.7≤σ / δ≤2.2,
where σ is the cavity groove height; δ is the width of the nozzle gap, the nozzle is equipped with a ring resonator with depth h with a cut edge in the form of a conical surface, the ring resonator is mounted on the bearing part of the body with the formation of grooves relative to the upper part of the resonator, the upper part of the body is made with a cone-shaped funnel paired with the cut edge of the resonator. 2. The ultrasonic liquid atomizer according to claim 1, characterized in that the nozzle deflector is installed in the housing with the possibility of axial movement coaxially with the central gas duct. 3. The ultrasonic liquid atomizer according to claim 1, characterized in that the nozzle diameter is selected from the condition:
d _c / λ = 1.09 · 1.3 ⁿ ,
where d _c is the diameter of the nozzle; λ is the wavelength of the excited oscillations;
n = 0; 1; 2; 3 .... 4. The ultrasonic liquid atomizer according to claim 1, characterized in that it is equipped with a set of ring resonators of different diameters with elements for their rigid fixation on the bearing part of the housing.

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