RU84257U1 - Vortex Radiator - Google Patents

Abstract

A vortex emitter containing a cylindrical chamber with a tangentially located fitting, having an opening along the axis of the end wall communicating with a cylindrical nozzle, the diameter of which is smaller than the diameter of the cylindrical chamber, characterized in that it further comprises a second cylindrical chamber with a cylindrical nozzle and tangentially located fitting directed opposite to the fitting of the first cylindrical chamber, while the second cylindrical chamber at ykaet to the end of the first side of its cylindrical nozzle, including its inside, the ends of cylindrical nozzles coincide and a cylindrical second nozzle the cylindrical chamber has a conical deflector.

Description

The utility model relates to devices for processing liquid in a sound field for dispersing, mixing and intensifying technological processes in the chemical industry, construction and other industries.

Known hydrodynamic dispersant - emitter pat. RU 2306971, the technical result of which is to increase the intensity of cavitation and the efficiency of the dispersion process.

The universal homogenizing hydrodynamic dispersant RU 2265478 is also known.

Known hydrodynamic emitter RU 2205073, which contains a nozzle, a resonant oscillating device, a housing of coaxial disks.

The closest technical solution is a vortex emitter, containing a cylindrical chamber with a tangentially located fitting, having an opening along the axis of the end wall that communicates with the cylindrical nozzle, the diameter of which is less than the diameter of the cylindrical chamber (see Acoustic technology of concrete. Edited by I.N. Akhverdov M , Stroyizdat. 1976.p.17).

However, the intensity of oscillations caused by spatial oscillation of the jet is negligible.

The essence of the utility model lies in the fact that the vortex emitter, containing a cylindrical chamber with a tangentially located fitting, having an opening along the axis of the end wall and communicating with a cylindrical nozzle, the diameter of which is smaller than the diameter of the cylindrical chamber, further comprises another cylindrical chamber coaxial with the first cylindrical chamber a chamber with a cylindrical nozzle and with a tangentially located fitting directed opposite to the fitting of the first cylindrical chamber, while Single cylindrical chamber adjacent to the first end from its cylindrical nozzle, including its inside, the ends of cylindrical nozzles coincide and a cylindrical second nozzle the cylindrical chamber has a conical deflector.

The essence of the utility model is illustrated in the drawing, where

figure 1 - General view of the vortex emitter;

figure 2 is a section I-I;

figure 3 is a section II-II;

4 is a section III-III.

The vortex emitter contains a cylindrical chamber 1 with a tangentially located fitting 2. The chamber 1 has an opening along the axis of the end wall that communicates with a cylindrical nozzle 3, the diameter of which is smaller than the diameter of the cylindrical chamber 1. The vortex emitter further comprises, located coaxially with the first cylindrical chamber 1, one more the second cylindrical chamber 4 and with a tangentially located nozzle 5 directed opposite to the nozzle 2 The second cylindrical chamber 4 with a cylindrical nozzle 6 is adjacent to the end the first chamber 1 from the side of its cylindrical nozzle 3, including it inside itself, while the ends of the cylindrical nozzles 3 and 6 coincide and the cylindrical nozzles 6 has a conical visor 7.

Vortex emitter operates as follows.

According to fitting 2, fluid under pressure enters the cylindrical chamber 1 tangentially to its inner surface: the rectilinear motion of the fluid turns into a curvilinear. Due to the law of conservation of momentum, the rotational flow rate at the exit from the cylindrical nozzle 3 increases and, in the absence of centripetal forces from the solid walls, the particles of the stream fly under the influence of centrifugal forces in space, forming a hollow asymmetric cone. A rotating stream is destroyed, forming a series of vortices, generating acoustic vibrations. When supplying liquids under pressure through the nozzle 5 (as described above), flow particles also fly out of the cylindrical nozzle 6, forming a hollow asymmetric cone. The fluids in both cones rotate in opposite directions, which, when they interact, enhances the vortex formation processes, and hence the acoustic vibrations. The conical visor 7 does not allow to extinguish the energy of the flow coming from the nozzle 6 from the environment, enhancing the interaction of the flows from the nozzles 6 and 3.

Claims (1)

A vortex emitter containing a cylindrical chamber with a tangentially located fitting, having an opening along the axis of the end wall communicating with a cylindrical nozzle, the diameter of which is smaller than the diameter of the cylindrical chamber, characterized in that it further comprises a second cylindrical chamber with a cylindrical nozzle and tangentially located fitting directed opposite to the fitting of the first cylindrical chamber, while the second cylindrical chamber at ykaet to the end of the first side of its cylindrical nozzle, including its inside, the ends of cylindrical nozzles coincide and a cylindrical second nozzle the cylindrical chamber has a conical deflector.