RU2185896C1 - Ultrasonic device (its variants) - Google Patents

Abstract

FIELD: development of ultrasonic oscillation systems for technological designation. SUBSTANCE: device having converter, concentrator and waveguide of bending oscillations also includes waveguide-irradiation system consisting of set of waveguides of longitudinal oscillations. The last are rigidly mounted in antinodes of oscillations of bending oscillation waveguides normally relative to their lengthwise axis. Bending oscillation waveguides and set of longitudinal oscillation waveguides are selected at experimental and estimation procedures. EFFECT: lowered energy consumption, enhanced efficiency of process, increased volume or surface area of treated object. 9 cl, 24 dwg

Description

 The invention relates to the field of ultrasonic technology and can be used in the design of ultrasonic oscillatory systems for technological purposes, allowing several times to reduce energy costs, increase process productivity and increase the volume or area of the processed object.

 A device is known that contains a transducer, concentrator and a waveguide of longitudinal vibrations, which allows to obtain ultrasonic vibrations of high intensity [Gershlag D. A., Fridman V.M. "Ultrasonic Technological Equipment", "Energy", Moscow, 1976, p. 134-144]. The device is widely used in various technological processes, but it also has a significant drawback, namely, that the radiating surface of the waveguide has limited linear dimensions, so the volume or area of the treated object is also limited. In order to process large volumes or areas, several such systems are required, and for each system it is necessary to have a separate ultrasonic generator and transducer, which significantly increases the cost of installation and requires significant costs during operation.

 A device is known that contains a transducer with a concentrator and flexural waveguides, which makes it possible to obtain a fairly uniform ultrasonic field [Trizna Yu. P., Bertnik Yu.N., Kovalchuk VA, Voloshchuk VD, Teslya V.E. "Ultrasonic Emitter", ed. St. USSR 281045 from 11.24.1970]. The technological capabilities of the device are limited, since it can effectively work only on gas and liquid media with a low viscosity coefficient. It also cannot be used for processing solids of complex shape.

 A known ultrasonic device comprising a magnetostrictive transducer, a hub, a bending waveguide mounted perpendicular to the axis of the hub, and two longitudinal waveguides rigidly fixed to the ends of the bending waveguide [II. Theumin "Ultrasonic waveguides of bending vibrations". Physics and technology of powerful ultrasound. Sources of powerful ultrasound. Edited by prof. L.D. Rosenberg. Publishing house "Science", M .: 1967, p. 280, Fig. 15] is a prototype of the first embodiment of the device.

 As a prototype of the second invention, an ultrasonic device was selected, including a transducer, a hub, a cross-shaped bending waveguide mounted perpendicular to the longitudinal axis of the concentrator, and four longitudinal waveguides mounted at the ends of the bending waveguide perpendicular to its longitudinal axes [I.I. Theumin "Ultrasonic waveguides of bending vibrations". Physics and technology of powerful ultrasound. Sources of powerful ultrasound. Edited by prof. L.D. Rosenberg. Publishing house "Science", Moscow: 1967, p. 281, Fig. 16].

 A distinctive feature of these devices is that they can work on any type of medium: solid, liquid, gas.

 However, the known devices do not significantly affect the performance of the process and reduce energy costs.

The tasks to be solved by the invention are as follows:
1. Creation of a waveguide-emitting system capable of operating in various technological processes occurring in gas and liquid media with a high viscosity coefficient, for example, in metal melts, when working on a solid medium, for example, when cleaning metal from scale and carbon, during metal deformation, dimensional processing etc.;
2. Reducing energy costs by more than 10 times;
3. Increase more than 10 times the productivity of the process and increase the volume or area of the processed object.

 The tasks are solved in that the known devices containing a transducer, hub and bending waveguide in accordance with the invention have a wave-emitting system consisting of a set of longitudinal waveguides that are rigidly fixed in the antinodes of the vibration of the waveguides perpendicular to their longitudinal axis.

 The essence of the invention lies in the fact that experimentally and computationally selected bending waveguides and a set of waveguides of longitudinal vibrations.

 In the first embodiment, an ultrasonic device containing a transducer, a concentrator, a waveguide of bending vibrations, in the form of a narrow plate mounted perpendicular to the axis of the concentrator, and two waveguides of longitudinal vibrations mounted on the ends of the bending waveguide, is additionally equipped with waveguides of longitudinal vibrations, one of which is aligned with the concentrator, and the remaining waveguides of longitudinal vibrations are installed perpendicular to the plane of the bending waveguide in the antinode of the oscillations of the latter.

 The ultrasound device is equipped with at least one additional bending waveguide installed parallel to the main waveguide, the thicknesses of the main and additional waveguides are not equal to each other, while longitudinal waves (in the same way as in Section 1) are installed on the additional bending waveguide in the antinodes of vibrational displacements.

 An additional concentrator or longitudinal waveguide is installed between the concentrator and the bending waveguide.

 The waveguides of longitudinal vibrations are made in the form of rods, concentrators, rods with a nozzle-tool.

 In a second embodiment of the invention, an ultrasonic device comprising a transducer, a hub, a cross-shaped bending waveguide mounted perpendicular to the longitudinal axis of the concentrator, and four longitudinal waveguides mounted at the ends of the bending waveguide perpendicular to its longitudinal axes, is provided with additional longitudinal waveguides, one of which is installed in the center of the cross-shaped waveguide of bending vibrations is coaxial to the concentrator, and the remaining waveguides of longitudinal vibrations become perpendicular to the bending plane of the waveguide at the antinodes of the latter oscillations.

 An additional concentrator or longitudinal waveguide is installed between the concentrator and the bending waveguide.

 The waveguides of longitudinal vibrations are made in the form of rods, concentrators, rods with a nozzle-tool.

 In FIG. 1 shows a general view of an ultrasonic device; in FIG. 2 - the same top view (option 1); in FIG. 3 - an ultrasonic device with two parallel located waveguides of bending vibrations; in FIG. 4 - the same top view (claim 2 of the claims); in FIG. 5 - an ultrasonic device that is equipped with an additional longitudinal waveguide installed between the concentrator and the bending waveguide; in FIG. 6 is the same top view (claims 1 and 4 of the claims); in FIG. 7 - an ultrasonic device which is equipped with an additional concentrator installed between the main concentrator and the bending waveguide; in FIG. 8 is the same top view (claims 1 and 3 of the claims); in FIG. 9 - an ultrasonic device with two parallel located waveguides of bending vibrations, equipped with an additional waveguide of longitudinal vibrations located between the concentrator and the waveguides of bending vibrations; in FIG. 10 is the same top view (claim 2 and claim 4 of the claims); in FIG. 11 - an ultrasonic device with two parallel-located waveguides of bending vibrations, which is equipped with an additional concentrator of longitudinal vibrations located between the main concentrator and waveguides of bending vibrations; in FIG. 12 is the same, top view (claim 2 and claim 3 of the claims); in FIG. 13 - the shape of the waveguides of longitudinal vibrations in the form of rods; in FIG. 14 - the shape of the waveguides of longitudinal vibrations in the form of concentrators; in FIG. 15 - the shape of the waveguide-tool in the form of rods and hubs with a nozzle; in FIG. 16 is a general view of an ultrasonic device with a cross-shaped waveguide of bending vibrations; in FIG. 17 - the same top view (option 2); in FIG. 18 is an ultrasound device with a cross-shaped waveguide of bending vibrations, which is equipped with an additional longitudinal waveguide installed between the concentrator and the cross-shaped waveguide of bending vibrations; in FIG. 19 is the same, a top view (claim 8 of the claims); in FIG. 20 - an ultrasonic device with a cross-shaped waveguide of bending vibrations, which is equipped with an additional concentrator installed between the main concentrator and a cross-shaped waveguide of bending vibrations; in FIG. 21 is the same, a top view (claim 7 of the claims); in FIG. 22 - the shape of the waveguides of longitudinal vibrations in the form of rods; in FIG. 23 - the shape of the waveguides of longitudinal vibrations in the form of concentrators; in FIG. 24 - the shape of the waveguide-tool in the form of rods and concentrators with a nozzle.

 The device (option 1, Fig. 1, 2) contains a transducer 1, a concentrator 2, a waveguide 3 of bending vibrations, two waveguides 4 of longitudinal vibrations fixed at the ends of a bending waveguide 3, a set of additional waveguides 5 of longitudinal vibrations mounted perpendicular to the plane of the bending waveguide 3 in antinodes of the oscillations of the latter.

 The device (according to claim 2, Fig. 3, 4) contains, in addition to the above elements, an additional waveguide 6 of bending vibrations, the thickness of which is not equal to the thickness of the main waveguide 3. On the waveguide 6 of bending vibrations in the antinodes of vibrational displacements, waveguides 7 of longitudinal vibrations are installed.

 The devices according to claim 4 (FIGS. 5, 6 and 9, 10) in comparison with the devices in FIG. 1 to 4 further comprise a waveguide of 8 longitudinal vibrations.

 The devices according to claim 3 (FIGS. 7, 8 and 11, 12) in comparison with the devices in FIG. 1 to 4 further comprise a concentrator of 9 longitudinal vibrations.

 The device (option 2, Fig. 16, 17) contains a transducer 10, a hub 11, a cross-shaped waveguide 12 of bending vibrations mounted perpendicular to the longitudinal axis of the hub 11, four waveguides 13 of longitudinal vibrations mounted on the ends of the bending waveguide 12 perpendicular to its longitudinal axis, an additional waveguide 14 longitudinal vibrations installed in the center of the cross-shaped waveguide 12 coaxially to the hub, and additional waveguides 15 longitudinal vibrations mounted perpendicular to the plane of the bending waves yes 12 antinodes latter oscillations.

 The device according to claim 8 in FIG. 18, 19 contains, in addition to the above elements, an additional waveguide 16 of longitudinal vibrations.

 The device according to claim 7 of FIG. 20, 21 in comparison with the device in FIG. 16, 17 further comprises a hub 17.

 The devices operate as follows: when a high-frequency current converter 1 (or 10) is supplied to the field winding (not shown conventionally), longitudinal elastic vibrations arise in it, which are amplified and transmitted through the hub 2 (or 11) (directly or through additional waveguides 8, 16 and or concentrators 9, 17) to a waveguide of bending vibrations 3, 6 (or 12), in which longitudinal vibrations are converted into bending ones and transformed to waveguides 4, 5, 7 (or 13 - 15), where they are again converted to longitudinal vibrations. Thus, a system with several waveguides of longitudinal vibrations is obtained, for which separate sources of excitation (ultrasonic generators, transducers) are not required.

 The described waveguide-emitting system of longitudinal-bending-longitudinal vibrations can be installed in the bath for cleaning wide rolling strips, sheets and other products from scale and carbon deposits, for refining metal melt in large volumes, for obtaining metal powders from metal melt with a capacity of tens of kilograms per minute, processing liquids in large volumes and can be used to create technological and environmentally friendly processes, etc.

 At the same time, energy costs are reduced several times, since it is not required for each waveguide of longitudinal vibrations to use separate sources of excitation of ultrasonic vibrations (ultrasonic generators and transducers).

 Thus, the new distinctive features from the prototype signs provide a solution to the tasks, which gives reason to believe that the claimed technical solution meets the criteria of the invention of "novelty" and "inventive step".

Claims (9)

 1. An ultrasonic device containing a transducer, a concentrator, a waveguide of bending vibrations in the form of a narrow plate mounted perpendicular to the longitudinal axis of the concentrator, and two waveguides of longitudinal vibrations mounted on the ends of the bending waveguide, characterized in that it is equipped with additional longitudinal waveguides, one of which installed coaxially with the concentrator, and the remaining waveguides of longitudinal vibrations are installed perpendicular to the plane of the bending waveguide in the antinodes of the last .  2. The device according to p. 1, characterized in that it is equipped with at least one additional bending waveguide installed parallel to the main waveguide, the thicknesses of the main and additional waveguides are not equal to each other, while on the additional waveguide of bending vibrations in the antinodes displacements installed waveguides of longitudinal vibrations.  3. The device according to claim 1 or 2, characterized in that an additional concentrator is installed between the concentrator and the waveguide of bending vibrations.  4. The device according to claim 1 or 2, characterized in that between the concentrator and the waveguide of bending vibrations an additional waveguide of longitudinal vibrations is installed.  5. The device according to any one of paragraphs. 1-4, characterized in that the waveguides of longitudinal vibrations are made in the form of rods, concentrators, waveguides with a nozzle tool.  6. An ultrasonic device comprising a transducer, a concentrator, a cross-shaped bending waveguide mounted perpendicular to the longitudinal axis of the concentrator and four longitudinal waveguides mounted at the ends of the bending waveguide perpendicular to its longitudinal axes, characterized in that it is provided with additional longitudinal waveguides, one of which are installed in the center of the cross-shaped waveguide of bending vibrations coaxially with the concentrator, and the remaining waveguides of longitudinal vibrations at become perpendicular to the plane of the bending waveguide at the antinodes of the oscillations of the latter.  7. The device according to p. 6, characterized in that between the concentrator and the waveguide of bending vibrations installed an additional concentrator of longitudinal vibrations.  8. The device according to p. 6, characterized in that between the concentrator and the waveguide of bending vibrations installed an additional waveguide of longitudinal vibrations.  9. The device according to any one of paragraphs. 6-8, characterized in that the waveguides of longitudinal vibrations are made in the form of rods, concentrators, waveguides with a nozzle tool.

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