RU2501586C1 - Nozzle with swirler of double twist of flow - Google Patents

Abstract

FIELD: fire-fighting facilities.

SUBSTANCE: invention relates to the liquid spraying technique and can be used in fire-fighting equipment, the nozzle with a swirler of double twist of flow. At that it comprises a hollow housing with a nozzle and a central core. At that the housing is made with a channel for supplying liquid and has a coaxial sleeve rigidly connected to the housing with the nozzle secured to its lower part, made in the form of a cylindrical two-stage sleeve, the upper cylindrical stage of which is connected by a threaded connection with the central core mounted with the annular gap with respect to the inner surface of the cylindrical sleeve. At that consisting of a cylindrical part with the swirler coaxially fixed in its lower part, made in the form of a cylinder with a central orifice, on which outer surface at least double-helical thread is made, and in a central orifice the element of the secondary swirling of flow is fixed, at that made in the form of a cylindrical helical spring located flush with the upper end of the swirler, and protruding behind its lower end by an amount not exceeding the diameter of the central orifice.

EFFECT: increased efficiency of fine atomisation of liquid is achieved.

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Description

The invention relates to techniques for spraying liquids 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. 2445546, А62С 31/02, (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, a sprayer of this design does not allow to achieve a given distribution of flows of fine droplets on the irrigation surface of the required area without increasing the flow rate of the liquid. This is due to the fact that the droplet flows generated by most of the holes are oriented in the horizontal direction and have a symmetrical distribution relative to the horizontal plane at the outlet of the nozzle.

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

This is achieved by the fact that in a liquid nozzle containing a hollow body with a nozzle and a central core, the body is made with a channel for supplying liquid and has a coaxial sleeve rigidly connected to the body with a nozzle fixed in its lower part, made in the form of a cylindrical two-stage sleeve, the upper the cylindrical step of which is connected by means of a threaded connection to a central core installed with an annular gap relative to the inner surface of the cylindrical sleeve, and consisting of a cylindrical th part with a swirl fixed coaxially in its lower part, made in the form of a cylinder with a central throttle hole, on the outer surface of which at least a two-way screw thread is made, and in the central throttle hole there is a secondary element of the flow twist made in the form a coil spring located flush with respect to the upper end of the swirl, and protruding beyond its lower end by an amount not exceeding the diameter of the central throttle hole.

The drawing shows a structural diagram of the nozzle.

The nozzle with a double twist swirl includes a cylindrical hollow body 1 with a channel 3 for supplying fluid and a coaxial sleeve 2 rigidly connected to the body with a nozzle fixed in its lower part and made in the form of a cylindrical two-stage sleeve 4, the upper cylindrical step 6 of which is connected by a threaded connection with the Central core installed with an annular gap 9 relative to the inner surface of the cylindrical sleeve 4, and consisting of a cylindrical part 7 with fixed coaxially with it in the lower part of the swirler 10, made in the form of a cylinder with a central throttle hole 11, on the outer surface of which is made at least two-way screw thread 12, while options are possible both left and right screw surfaces on the cylinder of the swirler 10.

The annular gap 9 is connected with at least three radial channels 5, made in a two-stage sleeve 4, connecting it with an annular cavity 8 formed by the inner surface of the sleeve 2 and the outer surface of the upper cylindrical stage 6, and the annular cavity 8 is connected with the channel 3 of the housing 1 for fluid supply.

In the central throttle hole 11, a secondary flow twist element is fixed, made in the form of a cylindrical helical spring 13 located flush with respect to the upper end of the swirl 10 and protruding beyond its lower end by an amount not exceeding the diameter of the central throttle hole 11.

The nozzle with a swirl double twist flow is as follows.

Liquid under pressure is fed into the cavity of the nozzle body 1 and then flows in two directions: the first into the annular cavity 8 through radial channels 5 into the annular gap 9 between the nozzle and the central core. At inlet pressures of more than 0.2 MPa, the liquid accelerates on the outer cylindrical surface of the core with the formation of a liquid film that does not come off from its outer surface. Acceleration of the liquid in the lower part of this surface is accompanied by a decrease in its static pressure and, as a result, vaporization and the release of soluble gases. This phenomenon further prepares the liquid for crushing into small drops. Upon reaching the liquid flow of the counter-swirling flows flowing out of the swirl 10 and the element of the secondary twist of the stream, made in the form of a cylindrical coil spring 13, multiple crushing of the film occurs with the formation of a finely dispersed phase.

The execution of the element of the secondary twist of the flow, made in the form of a cylindrical coil spring 13, protruding beyond the lower end of the swirler 10 by an amount not exceeding the diameter of the central throttle hole 11, allows you to organize a turbulent flow from this element of the secondary twist of the stream.

The second direction in which the liquid enters is through the channel 3 for supplying liquid, then into the cavity of the central core, and then into the swirler 10, located in the lower part of the cylindrical part 7 of the core, from which the liquid flows out in a swirling swirl flow, with multiple droplets crushing fluid flows flowing out of the swirler 10 and the annular gap 9.

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 fields of technology where it is required to create atomized fluid flows in both closed and open spaces. A liquid nozzle can be used, for example, in stationary fire extinguishing systems of the sprinkler type, as well as 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)

A nozzle with a double twist flow swirl containing a hollow body with a nozzle and a central core, characterized in that the body is made with a channel for supplying fluid and has a coaxial sleeve rigidly connected to the body with a nozzle fixed in its lower part made in the form of a cylindrical two-stage sleeve the upper cylindrical step of which is connected by means of a threaded connection to a central core installed with an annular gap relative to the inner surface of the cylindrical sleeve, and consists a box from a cylindrical part with a swirl fixed coaxially in its lower part, made in the form of a cylinder with a central throttle hole, on the outer surface of which at least two-way screw thread is made, and in the central throttle hole there is a secondary element of the flow twist made in the form a coil spring located flush with respect to the upper end of the swirl and protruding beyond its lower end by an amount not exceeding the diameter of the central throttle bore TIFA.

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