RU2474451C1 - Pneumatic sprayer - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to spraying of fluids and may be used in firefighting equipment. Pneumatic sprayer comprises casing, training device, and nozzle. Vase is shaped to reversed cup with bottom provided with threaded hole to secure central cylindrical sleeve. Said sleeve has central axial bore of training device to feed fluid to be sprayed. Casing lateral surface has hole to feed air (gas) at pressure communicated with annular chamber. Said chamber is formed by cylindrical sleeve outer surface and casing inner surface. Cylindrical cartridge of training device feeding gas at pressure to sprayer via annular clearance is secured to casing lower part inner side surface. Said clearance is formed by cylindrical sleeve outer surface and casing inner surface. Nozzle shaped to conical funnel is secured coaxially to central cylindrical sleeve. End round plate with tapered orifices is rigidly secured perpendicular to funnel axis, at funnel lower part. Rows of cylindrical throttling orifices are made at funnel lateral surface, their axes being located in planes perpendicular to funnel axis.

EFFECT: higher efficiency of spraying.

1 dwg

Description

The invention relates to techniques for spraying liquid and can be used in fire fighting equipment, in agriculture, in chemical technology devices and in the power system.

The closest technical solution to the claimed object is the nozzle according to patent RU No. 2416445, А62С 31/02, a prototype containing a hollow body with a nozzle and a central core.

The use of a finely dispersed sprayer of the described design allows one to obtain a uniform volume flow of finely dispersed droplets in the range of droplet diameters from 30 to 150 microns with a water supply pressure of not more than 1 MPa. However, the sprayer of this design does not allow to achieve the specified distribution of the flows of fine droplets on the irrigation surface of the required area without increasing the flow rate of the liquid due to the absence of the gas component of the turbulent flow of the two-phase mixture.

The technical result is an increase in the efficiency of finely dispersed liquid spraying.

This is achieved by the fact that in a pneumatic nozzle containing a housing with a supply of sprayed liquid and gas, a jetting device and a sprayer, the housing is made in the form of an inverted cup, in the bottom of which a threaded hole is made for fastening to an axisymmetric housing, a central cylindrical insert with a central axial channel of the jetting device for supplying the sprayed liquid, and in the side surface of the housing, perpendicular to its axis, at least one hole for supplying air (g j) under pressure, which is connected to the annular chamber formed by the outer surface of the central cylindrical insert and the inner surface of the housing, and to the inner side surface of the housing, in its lower part, a cylindrical sleeve of the flow directing device for supplying gas under pressure to the atomizer through an annular gap is attached, formed by the outer surface of the central cylindrical insert and the inner surface of the sleeve, while the annular gap is connected to the annular chamber, and to the central A nozzle made in the form of a conical bell is coaxially mounted on the cylindrical insert, in the lower part of which, perpendicular to its axis, a circular end plate is rigidly attached with at least three conical throttle openings with an angle at the top of the cone lying in the range from 45º to 90º at the same time, at least two rows of cylindrical throttle holes with axes lying in planes perpendicular to the axis of the socket are made on the lateral surface of the socket, and at least three from Erste.

The drawing shows a structural diagram of a pneumatic nozzle.

The pneumatic nozzle contains a housing 6, made in the form of an inverted glass, in the bottom of which a threaded hole 2 is made for fastening to an axisymmetric housing 6, a central cylindrical insert 1 with a central axial channel 3 of a flow guide device for supplying the sprayed liquid, and in the side surface of the housing 6, perpendicular to it axis, made at least one hole 8 for supplying air (gas) under pressure, which is connected to the annular chamber 13, formed by the outer surface of the Central cylindrical insert 1 and the inner surface of the housing. A cylindrical sleeve 9 of the jetting device for supplying air (gas) under pressure to the atomizer is attached to the inner side surface of the housing 6, in its lower part, by means of an annular gap 10 formed by the outer surface of the central cylindrical insert 1 and the inner surface of the sleeve 9, while the annular gap 10 is connected to the annular chamber 13. To the central cylindrical insert 1 is a coaxially mounted atomizer made in the form of a conical socket 4, in the lower part of which, perpendicular to its axis, w The end face round plate 5 is firmly attached with at least three conical throttle holes 12 with an angle at the top of the cone lying in the range from 45º to 90º. At least two rows of cylindrical throttle holes 11 are made on the side surface of the bell, with axes lying in planes perpendicular to the axis of the bell 4, and at least three holes are made in each row.

Pneumatic nozzle operates as follows.

Liquid under pressure is supplied through an axial channel 3 made in the central cylindrical insert 1 to the atomizer in the form of a conical socket 4, from which part of the liquid flows out in the horizontal direction through the radial holes 11, and part in the vertical direction through the conical throttle openings 12. Air under pressure is supplied through the openings 8 to the annular chamber 13, and from it to the atomizer by means of an annular gap 10. In this case, multiple drops of liquid flows flowing from the throttle are crushed holes. The presence of gas inclusions in a liquid additionally perturbs its surface, which leads to wave formation and volumetric crushing of the liquid film. The loss of mechanical energy during external acceleration (on the external conical surface) is reduced compared with the same acceleration in a closed channel.

The nozzle can be used in various branches of technology where it is required to create atomized fluid flows in both closed and open spaces, for example, in stationary fire extinguishing systems, and also in motor engineering for spraying fuel. In addition, the nozzle can be used in various technological processes, in which it is required to ensure high efficiency of heat and mass transfer processes when spraying liquids.

Claims (1)

Pneumatic nozzle containing a housing with a supply of sprayed liquid and gas, a jetting device and a sprayer, characterized in that the housing is made in the form of an inverted cup, the bottom of which has a threaded hole for mounting an axisymmetric housing of a central cylindrical insert with a central axial channel of the spraying device for supplying a sprayable liquid, and in the side surface of the housing perpendicular to its axis, at least one hole for supplying air (gas) along d pressure, which is connected to the annular chamber formed by the outer surface of the Central cylindrical insert and the inner surface of the housing, and to the inner side surface of the housing in its lower part is attached a cylindrical sleeve of a flow directing device for supplying gas under pressure to the atomizer through an annular gap formed by the outer surface of the central cylindrical insert and the inner surface of the sleeve, while the annular gap is connected to the annular chamber, and to the central qi the nozzle is coaxially mounted to the indric insert in the form of a conical bell, in the lower part of which a circular end plate is rigidly attached perpendicular to its axis with at least three conical throttle openings with an angle at the top of the cone lying in the range from 45 ° to 90 °, at the same time, at least two rows of cylindrical throttle holes are made on the side surface of the socket, with axes lying in planes perpendicular to the axis of the socket, and at least three holes are made in each row.