RU2332266C1 - Ultrasonic vibration system - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention refers to ultrasonics and can be used for ultrasonic devices designed for high-intensity ultrasonic vibration effect on liquid environments. Ultrasonic vibration system with extended radiating surface is intended for introduction of higher intensity ultrasonic vibration to technological environments at vibration intensity of more than 10 Wt/cm² and structurally contains ultrasonic converter, matching acoustic-type transformer and waveguide-analysing system. Ultrasonic piezoelectric converter is multipackaged and structurally contains piezoelectric elements assembly generating ultrasonic vibrations of energy that is accumulated in front frequency-lowering facing and transferred, through matching acoustic-type transformer, to waveguide-analysing system.

EFFECT: design of ultrasonic system enabling for ultrasonic vibration of higher intensity introduced to technological environments at vibration intensity of more than 10 Wt/cm².

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Description

The invention relates to the field of ultrasonic technology and can be used to create ultrasonic devices for exposure to liquid media by ultrasonic vibrations of high intensity.

It is known that high-intensity ultrasonic vibrations and the nonlinear acoustic effects resulting from them in liquid media (cavitation, acoustic flows, flotation effect, and others) contribute to the acceleration of various physical and chemical processes. To influence liquid media with high-intensity ultrasonic vibrations, special devices are created - ultrasonic oscillatory systems that convert the energy of an alternating electric current of ultrasonic frequency into elastic mechanical vibrations, their transformation and radiation into a technological medium.

A typical representative of devices of this type are ultrasonic oscillatory systems made according to various structural schemes, the most effective of which is considered to be half-wave [1]. In such designs, the conversion of electrical vibrations into elastic mechanical ones is carried out by a piezoelectric transducer, which is a package of ring-shaped piezoelectric elements, compressed between the front (working) and rear (reflective) frequency-lowering plates. An oscillating speed transformer — a hub — is acoustically coupled to the front frequency-lowering pad — a hub that matches the acoustic impedances of the piezoelectric transducer and the process medium by transforming the vibrational velocity in a longitudinal acoustic wave.

In an ultrasonic oscillatory system made according to a half-wave design scheme, the front working frequency-lowering pad simultaneously serves as a hub.

A “mushroom-shaped” emitter is connected to the output end of the concentrator, the radiating surface of which has the form of a disk whose diameter exceeds the diameter of the output end of the concentrator.

Currently, a large number of structural implementations of ultrasonic oscillatory systems are known, which differ in size, types of materials used, operating frequency, and quality factor. However, they all share common flaws:

- limited radiation surface area, which does not allow to output large powers (over 500 W) into the process media at a given intensity of effective cavitation (10 ... 15 W / cm ² ). This disadvantage leads to low productivity of ultrasonic technologies, which limits their practical application;

- the limiting value of the diameter of the disk-shaped radiator is limited by the occurrence of bending vibrations and a decrease in the efficiency such emitters.

These disadvantages are partially eliminated in the ultrasonic device [2, prototype]. An ultrasonic device comprises an ultrasonic transducer and an acoustically associated wave-emitting system. A wave-emitting system with a developed radiating surface contains coaxially mounted waveguides of bending vibrations, separated by sections of the waveguide of longitudinal vibrations. The waveguides of bending vibrations are located in areas perpendicular to the axis of the waveguide of longitudinal vibrations at distances λ / 4 from each other, where λ is the wavelength of longitudinal vibrations. The thickness of the waveguides of bending vibrations located in the antinodes of longitudinal vibrations is λ / 15. The thickness of each of the other waveguides of bending vibrations λ / 18. The total emitter length is a multiple of λ / 2. The prototype allows you to provide a large area of the radiating surface, in comparison with [1], and, as a consequence, a high radiation power, to evenly distribute vibrations in extended technological volumes. As an ultrasonic transducer in the prototype, a magnetostrictive or piezoelectric transducer is used.

The use of emitters with a developed surface, as in the prototype, made it possible to increase the output of the energy of ultrasonic vibrations into technological media in a cavitation mode (with an oscillation intensity of 10 ... 15 W / cm ² , the amplitude of vibrational displacements of more than 20 μm). So, for example, with an emitter diameter of 40 ... 45 mm, a length of (5..7) · λ / 2 and a total radiation area of about 200 cm ² , it became possible to output ultrasonic vibrations with a power of 2000 ... 3000 W into technological media. Given the efficiency existing magnetostrictive and piezoelectric ultrasonic transducers (40% ... 70%) there is a need to use ultrasonic transducers as part of the ultrasonic vibrational system, capable of generating ultrasonic vibrations when applying electrical vibrations with a power of at least 3 ... 6 kW. Obviously, the surface of the formation of ultrasonic vibrations in the transducer must be no less than the radiation surface, and the condition for ensuring the operation of the magnetostrictive or piezoelectric material in conditions not exceeding the mechanical strength of the ceramic or welded joint (i.e., the vibration amplitude should not exceed 5 μm) must be satisfied. The need to fulfill this condition necessitates an increase in the surface area of the formation of ultrasonic vibrations not less than 4 ... 5 times, compared with the radiation area, that is, to values exceeding 1000 cm ² . Consequently, the transducer must have transverse dimensions exceeding half the length of the ultrasonic vibrations in the material at the operating frequency.

With such overall dimensions of the transducer, low-frequency radial and contour vibrations occur that cause a decrease in efficiency, mechanical properties (strength, rigidity) of the structure deteriorate, and the cooling efficiency of the inner regions of the active material is reduced. A decrease (2 ... 3 times) in the efficiency of converting the energy of electrical vibrations into ultrasonic and the destruction of piezoceramic elements make the manufacture and use of large-area transducers a technically impossible task. Due to the fact that magnetostrictive converters have a low efficiency (less than 50%), they are increasingly being replaced by piezoelectric transducers having an efficiency over 70% and not requiring forced liquid cooling. The use of piezoelectric elements in the construction of such ultrasonic oscillatory systems is ineffective, due to the limited size of the piezoelectric elements produced by the industry (not more than 70 mm in diameter).

The disadvantages considered make it impossible to use a prototype when implementing ultrasonic technologies with the output of high-energy ultrasonic vibrations into the process volume in cavitation mode due to the inability to create the necessary power vibrations with the available ultrasonic transducers.

The proposed technical solution allows for the generation of ultrasonic vibrations sufficient to ensure the cavitation mode of power without exceeding the maximum permissible parameters of the piezoelectric elements.

The technical result is expressed in the creation of an ultrasonic oscillatory system, which provides the introduction of ultrasonic vibrations of the required power into the technological environment at a given intensity of cavitation due to the use of a piezoelectric transducer, which allows you to summarize the power of ultrasonic vibrations generated by a set of packages of piezoelectric elements of small sizes.

The essence of the proposed technical solution lies in the fact that in the known ultrasonic oscillatory system, consisting of an ultrasonic transducer, matching acoustic transformer and wave-emitting system, the ultrasonic transducer contains one working frequency-lowering pad, made in the form of a body of revolution, tapering along the length of the section, limited to sides of the acoustic connection with the matching acoustic transformer with a flat end surface, and on the opposite side - a surface formed by flat faces symmetrically relative to the longitudinal acoustic axis at equal distances from the center of the flat end surface, multiples of an odd number of quarters of the length of the longitudinal acoustic wave in the material of the frequency-lowering lining at the working frequency of the ultrasonic vibrating system, with each surface face working frequency of the lowering pad, one end surface of the packet consisting of an even number of piezoelectric elements is acoustically connected, the number of packages of piezoelectric elements is equal to the number of flat faces, the other end surface of each package of piezoelectric elements is acoustically connected to the reflective frequency-lowering pad, the number of which is equal to the number of packages of piezoelectric elements, and the acoustic length of each package of piezoelectric elements and the associated reflective frequency-lowering pad corresponds to a quarter the length of the longitudinal acoustic wave in the material of the working frequency-lowering lining.

The proposed technical solution is illustrated in figures 1-3. Figure 1 shows a diagram of the proposed ultrasonic oscillatory system. Pos.1 - wave-emitting system, pos.2 - matching acoustic transformer, pos.3 - working frequency-lowering pad, pos.4 - piezoelectric elements, pos.5 - reflecting frequency-lowering pads.

Figure 2 presents a perspective view of ultrasonic transducers. On figa presents an ultrasonic transducer with three packages of piezoelectric elements, and on figb with seven packages.

Figure 3 presents a perspective view of the working frequency-lowering plates of ultrasonic transducers. On figa - with three faces, on figb - with seven faces.

In laboratory and industrial conditions, the created ultrasonic oscillatory systems are investigated, the ultrasonic transducers of which contain from three to seven packages of piezoelectric elements. The radiation power to the aquatic environment by an ultrasonic vibrating system containing an ultrasonic transducer based on three packages of piezoelectric elements is 1.6 kW, and an ultrasonic vibrating system containing an ultrasonic transducer consisting of seven packages of piezoelectric elements is up to 3.5 kW. The efficiency of the considered oscillatory systems reaches 0.8.

The appearance of the ultrasonic oscillatory system, comprising an ultrasonic transducer, consisting of seven packages of piezoelectric elements, shown in figure 4.

Currently, the Biysk Technological Institute for industrial applications is preparing the production of industrial ultrasonic technological devices, which include the created oscillatory systems.

Information sources

1. Ultrasonic oscillatory system: US Pat. 2141386 Russian Federation: IPC ⁶ В06В 3/00. / V.N.Khmelev, R.V. Barsukov, S.N. Tsyganok; applicant and patent holder GOU VPO Altai State Technical University named after I.I.Polzunova. " - No. 97120873; declared 12/15/97; publ. 11/20/99, bull. Number 32. - 7 p.: Ill.

2. Ultrasonic device: US Pat. 2248850 Russian Federation: IPC ⁷ В06В 1/06, G01N 29/00. / N.P. Kolomeets, A.A. Novik; Applicant and patent holder of Ultrasonic equipment inlab LLC. - No. 2004118752/28; declared 06/21/2004; publ. 03/27/2005, bull. No. 9 is a prototype.

Claims (1)

An ultrasonic oscillating system consisting of an ultrasonic transducer, matching acoustic transformer and wave-emitting system, characterized in that the ultrasonic transducer contains one working frequency-lowering pad, made in the form of a body of revolution, tapering along the length of the section, limited from the side of the acoustic connection with matching acoustic transformer flat end surface, and on the opposite side - a surface formed by flat faces, located symmetrically with respect to the longitudinal acoustic axis at equal distances from the center of the flat end surface, multiples of an odd number of quarters of the length of the longitudinal acoustic wave in the material of the frequency-lowering lining at the working frequency of the ultrasonic vibrating system, one end surface is acoustically connected to each face of the working frequency-lowering lining a package consisting of an even number of piezoelectric elements, the number of packages of piezoelectric elements being equal to for flat faces, the other end surface of each package of piezoelectric elements is acoustically connected to a reflective frequency-lowering pad, the number of which is equal to the number of packages of piezoelectric elements, and the acoustic length of each package of piezoelectric elements and the associated reflective frequency-lowering pad corresponds to a quarter of the length of the longitudinal acoustic wave in the material of the working frequency-lowering lining.

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