CS210465B1 - Acoustic radiator for the liquids - Google Patents

Description

USOSLOVENSKÁSSKÁSOCIALISTÁREF USER DESCRIPTION OF THE INVENTION CERTAIN CERTIFICATE 210465 (11) (Bl) (51) Int. Cl.3 r Λ G 01 H 3/12 (22) Enrolled 25 10 79 (21) (PV 7224-79) (40) Published 29 05 81 OFFICE AND DISCOVERY OFFICE (45) Published 15 02 83 (75)

Author of the invention ŠVEHLA ŠTEFAN ing. CSc., NEW CITY over VÁHOM (54) Acoustic emitter for liquids 1

BACKGROUND OF THE INVENTION The present invention relates to an embodiment of an acoustic radiator for liquids.

The previously known mechanical vibrator is a magnetostrictive transducer provided with end plates connected to the bending springs in the center of which tools are required for the processing of the minerals. When the magnetostrictive transducer is oscillating, the bent springs are compensated, causing them to bend, causing the bias of the spring to increase perpendicularly to the axis and to the direction of the transducer, which is transmitted to the transducer. tools placed in the center of the springs. Such vibratory vibrators of about 10 meters in size for the mining and geological industries.

Another known solution utilizes a bending radial semi-wavelength mechanical concentrator with an internal cavity at the expanding end to transform the longitudinal oscillations. On this principle, several cavity concentrators are provided. The first solution of a mechanical vibrator is insufficient to be unsuitable for fluid environments. A disadvantage of the second solution is that it produces a small radial deflection.

The above-mentioned drawbacks are alleviated by the technical problem of solving the acoustic radiator of the invention, which is that the surface of the acoustic transducer is provided with a tubular diaphragm to which it is fixedly attached to the ends of the transducer. is broken on the inverter. The essence is that the inverter is surrounded by a reflector without contact.

According to the present invention, the acoustic emitter is designed to transform the transducer amplitudes and transients of the transducer into a larger amplitude deflection amplitude of the large flat membrane, thereby achieving greater acoustic radiated output to the liquid medium.

In the accompanying drawing, a schematic exemplary embodiment of an acoustic radiator in a section is shown.

An acoustic fluid emitter consists of its own acoustic transducer 1, which is a surface provided with a diaphragm 2 in a shaping tube. The ends of the diaphragm 2 are fixedly attached to the acoustic transducer 1. The diaphragm 2 is broken off on the acoustic transducer 1. The acoustic transducer 1 is non-contacted by the reflector 3. The acoustic transducer 1 excels the standing wave with a long oscillation, causing stretching and compressing the diaphragm 2. This causes the membrane to have 2-way oscillations with radial radiation of acoustic energy with maximum amplitude.

Claims (3)

Acoustic radiator for fluids, characterized in that the surface of the acoustic transducer (1) is provided with a tube-shaped membrane (2), the ends of which are fixedly connected to the ends of the acoustic transducer (1). Acoustic radiator according to claim 1, characterized in that the diaphragm (2) is convex on the acoustic transducer (1). Acoustic radiator according to claim 1, characterized in that the acoustic transducer (1) is contactlessly surrounded by a reflector (3). 1 sheet of drawings