RU2668897C1 - Acoustic atomizer - Google Patents

Abstract

FIELD: devices for liquid atomization or spraying.SUBSTANCE: invention relates to sprayers of fluids, solutions and can be used in engine building, chemical, food and light industry. Acoustic nozzle contains a housing with an internal acoustic oscillation generator in the form of a nozzle and a resonator, tubes for supplying air and liquid. Body is made in the form of a glass with a bottom. Body is provided with a cylindrical cavity for supplying liquid through a tube located in the cover, in the upper part of which there is a fixing the upper part of the rod of the rod gas-jet radiator in the nozzle formed in the cover. Upper part of the rod is hingedly connected to the lower part of the radiator in the cover of at least one fixing disc made in the form of at least three elastic lobes interacting with the inner surface of the conical opening of the cover. Between the hole in the bottom of the body and the outer surface of the nozzle cover is a slotted channel, through which the liquid enters. Between the inner surface of the tapered hole and the outer surface of the lower part of the rod, an annular channel is provided through which the atomizing agent enters. External diffuser of the atomizer is coaxially attached to the lower part of the nozzle body. Internal perforated diffuser is fixed to the conical surface of the rod jet-edge generator in such a way that the output sections of the external and internal diffusers lie in the same plane which is perpendicular to the axis of the jet-edge generator. Additional flow divider coaxially attached to the external diffuser is made in the form of a cylindrical shell, at the end part of which a perforated plate is fixed on the side opposite the diffuser.EFFECT: technical result of invention is higher efficiency of spraying.1 cl, 1 dwg

Description

The invention relates to means for spraying liquids, solutions, and can be used in engine building, chemical, food and light industries.

The closest technical solution to the claimed object is an acoustic spray nozzle according to the patent of Russian Federation No. 2345280, comprising a housing with an acoustic oscillator located inside the nozzle and resonator, made in the form of concentric annular slots located in a plane perpendicular to the axis of the housing, the ring is conical surface associated with the housing, and a spray, which serves to form a liquid film that blocks the exit from the generator, and is fixed in the housing by a hollow rod of the swirler on the end screw and a shoulder to accommodate an annular platform on which the fluid flows from the atomizer (prototype).

A disadvantage of the known acoustic nozzle is that it does not provide a high degree of atomization.

The technical result is an increase in spraying efficiency.

This is achieved by the fact that in an acoustic nozzle containing a housing with an acoustic oscillation generator located in the form of a nozzle and a resonator, tubes for supplying air and liquid, the housing is made in the form of a cup with a bottom; a housing in which a cylindrical cavity for supplying fluid through the tube located in a lid, in the upper part of which there is a fastening fixing the upper part of the rod of the rod gas-jet emitter in the nozzle made in the lid, and the upper part of the rod is pivotally connected to the lower part the emitter in the cover of at least one fixing disk, made in the form of at least three elastic petals interacting with the inner surface of the conical opening of the cover, and between the opening in the bottom of the housing and the outer surface of the nozzle of the cover there is a slotted channel through which fluid enters, and between an annular channel is made on the inner surface of the conical hole and the outer surface of the lower part of the rod, along which the spraying agent enters, and the ratio _{of the} emitter height h ₁ standing h between the upper base of the conical surface and the lower end surface of the nozzle lies in the optimal range of values: h ₁ / h = 1 ÷ 3; the ratio of the inner diameter d _{1 of} the emitter cavity to the diameter d _{2 of} its outer cylindrical surface lies in the optimal range of values: d ₁ / d ₂ = 0.7 ÷ 0.9; the ratio of the inner diameter d _{1 of} the emitter cavity to the diameter d of its rod lies in the optimal range of values: d ₁ / d = 1 ÷ 3; the ratio of the inner diameter d _{1 of the} cavity of the emitter 4 to the height h _{1 of the} cavity lies in the optimal range of values: d ₁ / h ₁ = 1 ÷ 1.5, to the lower part of the nozzle body, an external diffuser of the atomizer is coaxially attached, and to the conical surface of the rod gas-jet Hartmann emitter, an internal perforated diffuser is attached, so that the output sections of the external and internal diffusers are in the same plane perpendicular to the axis of the gas-jet emitter, and an additional divider is coaxially attached to the external diffuser flow, made in the form of a cylindrical shell, on the end part of which, from the side opposite to the diffuser, a perforated plate is fixed.

The drawing shows a General view of an acoustic nozzle for spraying liquids.

The acoustic nozzle comprises a housing 5 made in the form of a cup with a bottom, in which a cylindrical cavity 1 is made for supplying liquid through a tube 16 located in the cover 6. In the nozzle housing 5, a cylindrical groove 8 is provided, in which an elastic sealing element 9 is located, wherein the cover 6 and the housing 5 is connected by screws 7. In the upper part of the lid there is a fastener 10 that fixes the upper part of the rod 12 of the Hartmann rod gas-jet emitter 4, made in the nozzle 18. Through the slotted channel 11, it enters the nozzle 18 pylivayuschy agent. Between the hole in the bottom of the housing 5 and the outer surface of the nozzle 18 of the cover 6, a slotted channel 2 is made, through which liquid enters. An annular channel 3 is made between the inner surface of the conical hole 17 and the outer surface of the lower part of the rod 13, through which a spraying agent, for example, air, enters.

The upper part of the rod 12 is pivotally connected to the lower part of the rod 13, which is fixed relative to the conical hole 17 made in the cover 6, by means of at least one fixing disk 14 made in the form of at least three elastic petals 15 interacting with the inner surface of the conical cover holes 6.

For optimal operation of the nozzle, the following ratios of its parameters must be observed:

The ratio of the height h _{1 of the} emitter 4 to the distance h between the upper base of the conical surface 19 and the lower end surface of the nozzle 18 lies in the optimal range of values: h ₁ / h = 1 ÷ 3;

The ratio of the inner diameter d _{1 of the} cavity 20 of the emitter 4 to the diameter of its outer cylindrical surface lies in the optimal range of values: d ₁ / d ₂ = 0.7 ÷ 0.9;

The ratio of the inner diameter d _{1 of the} cavity 20 of the emitter 4 to the diameter d of its rod lies in the optimal range of values: d ₁ / d = 1 ÷ 3;

The ratio of the inner diameter d _{1 of the} cavity 20 of the emitter 4 to the height h _{1 of the} cavity 20 lies in the optimal range of values: d ₁ / h ₁ = 1 ÷ 1,5.

An external diffuser of the nozzle is coaxially attached to the lower part of the nozzle body 5, and an internal perforated diffuser 22 is attached to the conical surface 19 of the rod gas jet emitter 4 of Hartmann, so that the output sections of the external 21 and internal 22 of the diffusers lie in the same plane perpendicular to the axis gas-jet emitter 4.

The acoustic nozzle operates as follows.

Liquid under pressure is supplied to a cylindrical cavity 1 located outside the emitter 4, from where it flows through the slotted channel 2 in the form of a film, which is subjected to fluctuations in speed and pressure generated by pulsating shock waves that occur near the annular channel 3 due to the supersonic jet flowing onto the resonator 4. As a result, the film is crushed into small droplets, which together with the air stream form a torch of atomized liquid.

An option is possible when an additional flow divider is made coaxially attached to the external diffuser 21, made in the form of a cylindrical shell 23, on the end part of which, from the side opposite to the diffuser 21, a perforated plate 24 is fixed.

It is possible that in the cylindrical shell 23 with a perforated plate 24 fixed on its slice, an additional flow divider is placed, made in the form of at least two screw drums 27 and 28, mounted for rotation on the rods 25 and 26, one end of which is fixed in the center of the perforated plate 24, and the other on the inner surface of the cylindrical shell 23, while the location of the helical grooves on the helical drums 27 and 28 is opposite.

Claims (2)

1. An acoustic nozzle containing a housing with an acoustic oscillation generator located in the form of a nozzle and a resonator, tubes for supplying air and liquid, the housing is made in the form of a glass with a bottom, a cylindrical cavity is made in the housing for supplying fluid through a tube located in the lid, the upper part of which is fastening, fixing the upper part of the rod of the rod gas-jet emitter in the nozzle made in the lid, and the upper part of the rod is pivotally connected to the lower part of the emitter in the lid at the edge at least one fixing disk made in the form of at least three elastic petals interacting with the inner surface of the conical hole of the cover, and between the hole in the bottom of the housing and the outer surface of the nozzle of the cover there is a slotted channel through which fluid enters, and between the inner surface of the conical hole and the outer surface of the lower part of the rod has an annular channel through which enters atomizing agent, wherein the ratio of the height h of the radiator ₁ to the distance h between the upper bases Niemi conical surface and the lower end surface of the nozzle lies in an optimum range of values: h ₁ / h = 1 ÷ 3; the ratio of the inner diameter d _{1 of} the emitter cavity to the diameter d _{2 of} its outer cylindrical surface lies in the optimal range of values: d ₁ / d ₂ = 0.7 ÷ 0.9; the ratio of the inner diameter d _{1 of} the emitter cavity to the diameter d of its rod lies in the optimal range of values: d ₁ / d = 1 ÷ 3; the ratio of the inner diameter d _{1 of the} cavity of the emitter 4 to the height h _{1 of the} cavity lies in the optimal range of values: d ₁ / h ₁ = 1 ÷ 1.5, to the lower part of the nozzle body, an external diffuser of the atomizer is coaxially attached, and to the conical surface of the rod gas-jet emitter Hartmann attached an internal perforated diffuser so that the output sections of the external and internal diffusers lie in the same plane perpendicular to the axis of the gas-jet emitter, characterized in that the external diffuser is coaxially attached ny flow divider configured as a cylindrical shell, on which the end portion on the side opposite the diffuser, fixed perforated plate. 2. An acoustic nozzle according to claim 1, characterized in that in the cylindrical shell with a perforated plate fixed on its slice there is an additional flow divider made in the form of at least two screw drums mounted for rotation on the rods, one end of which is fixed in the center of the perforated plate, and the other on the inner surface of the cylindrical shell, while the location of the helical grooves on the screw drums is the opposite.

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