SU485780A1 - Ultrasonic nozzle - Google Patents

Description

one

The invention relates to the technique of dissolution of liquids, natural liquid and to be used in the combustion chambers and furnaces of various power plants.

Ultrasonic nozzles are known, comprising a housing with a distributor and a swirler in the form of a chamber with spiral inlets and a nozzle. Their disadvantages are the considerable consumption of the spraying agent and the poor quality of the dissolution.

The aim of the invention is to eliminate these drawbacks by organizing the flow of a nar-liquid mixture through a multi-stage ultrasonic resonator. This is achieved in the proposed nozzle by the fact that cylindrical cavities-resonators are made at the exit of the channels on the inner walls of the chamber, and toroidal cavities are between the inlets and the seat.

FIG. 1 shows a nozzle according to the invention, longitudinal section; in fig. 2 is a view along arrow A in FIG. one; in fig. 3 is a section according to BB and FIG. 2

The nozzle includes a housing 1 with channels 2 and 3 for supplying steam and fuel oil, secured therein by means of a cap nut 4, a distributor 5 of a steam oil mixture with holes 6 and 7 and a swirler 8 with

spiral input channels 9. a twisting chamber 10 n the nozzle 11. On the inner walls of the chamber 10 swirler 8 at the exit of the spiral channels 9 there are cylindrical cavities-resonators 12, and between the input channels 9 and the nozzle 11 - toroidal cavity-resonators 13. Grooves-resonators 13 can be located on the inner walls of the scorcher 8 different

in order to obtain in the swirling chamber 10 the desired forms of acoustic ultrasonic field) i level of oscillation concentration.

When feeding steam and fuel oil through channels 2 and 3 into the nozzle, their mixture passes through distributor 5 P and swirls 8 into chamber 10 partially through holes 6 and spiral channels 9, and partially directly through hole 7. At the exit of channels 9 fuel oil mixture. gets into the cavities of the resonators 12 and, interacting at the output of the nanocontext with the main note, generates ultrasonic vibrations that promote the intensive crushing of fuel droplets. Then, mixing with the non-swirling flow from the opening 7, the vapor-fuel oil mixture generates ultrasonic vibrations in the toroidal grooves-resonators 13 and goes through an intensive ultrasonic field.