RU2298299C1 - Ultrasound magnetostrictive transformer - Google Patents

Abstract

FIELD: ultrasound engineering.

SUBSTANCE: ultrasound magnetic transformer includes magnetic duct, composed of monolithic plates, each one of which is made of central element in form of ring, and at least three, mainly two-rod, semi-wave elements, positioned symmetrically along periphery of central element. Semi-wave elements are made with shifting of their longitudinal axis relatively to geometrical center of magnetic duct, and central element is made with width of ring equal to width of rod of semi-wave element, while each semi-wave element is positioned so that longitudinal symmetry axis of one of rods is a tangent to middle circle of central element. Aperture of central element is made with diameter, value of which is determined from given dependence.

EFFECT: improved functional and expanded technological capabilities.

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Description

The invention relates to ultrasonic technology and can be used in technological equipment of various sectors of the economy.

A known ultrasonic transducer, the magnetic circuit of which is a single half-wave rod, is composed of magnetostrictive plates, each of which has the shape of a rectangle [1].

The main disadvantage of this transducer is its low efficiency (hereinafter referred to as efficiency), due to significant losses in magnetic fluxes of scattering, which are caused by the fact that the magnetic circuit of this transducer has an open magnetic flux.

A magnetostrictive transducer is also known, in which, in order to eliminate losses due to magnetic fluxes of scattering, each plate of the magnetic circuit consists of three half-wave rods and two overlays, which serve to close the magnetic flux and form the radiating surfaces of the transducer. [2].

The limited technological capabilities of this transducer are its main disadvantage, which is due to the fact that the radiation of vibrations by this transducer is carried out only from two surfaces and these vibrations propagate in the direction along only one axis, which is the longitudinal axis of symmetry of the transducer.

In addition, an ultrasonic transducer is known that provides vibration radiation, for example, from four surfaces and in the direction along two axes intersecting at an angle of 90 degrees, which characterizes this transducer, in comparison with the above, as having wider technological capabilities [3].

The magnetic circuit of this transducer is formed by monolithic magnetostrictive plates, each of which consists of one central annular and four half-wave double-rod elements located radially and symmetrically around the periphery of the ring element, the hole diameter of which is made 0.05-0.3 L, where L is the length of the longitudinal ultrasonic waves in the transducer material. Half-wave elements, the length of the rods of which is equal to L / 2, are located so that the axis of their longitudinal symmetry passes through the geometric center of the plate and, therefore, the magnetic circuit. The excitation winding of this converter is laid on the rods and passes through the windows, which are formed by the rods, the outer rods of the rods and the ring element, which is also an overlay for all the rods of the converter, but already internal relative to their location.

However, this converter, which in its technical essence is closest to the proposed one and adopted as a prototype, has a number of significant drawbacks.

Firstly, due to the fact that the masses of the sections of the inner plates located above each of the rods of the half-wave element are equal to each other, the converter does not have a range of resonant frequencies, i.e. It has a very narrow, almost absent, bandwidth of the amplitude-frequency characteristic.

Secondly, the radiating surface of the transducer, i.e. the surface of the wall of the hole, performs only radial vibrations. This is due to the fact that the half-wave elements of the transducer are designed in such a way that their longitudinal axis of symmetry passes through the geometric center of the magnetic circuit.

Thirdly, the central hole of the transducer can have a maximum diameter of no more than 0.3 L, which is in the manufacture of transducer plates from K-65 alloy and at the calculated frequency of its half-wave elements of 19.5 kHz, i.e. at the frequency most commonly used in industry, corresponds to 78 millimeters.

Fourth, the implementation of a Central hole with a diameter of 0.05-0.3 L leads to the fact that the width of the annular element is always smaller than the width of the rod of the half-wave element, and the length of the average circumference of the annular element is not a multiple of half the length of the ultrasonic wave in the material of the magnetic circuit. As a result, this converter can be characterized as not having the highest possible efficiency.

The technical problem, the solution of which the invention is directed, is to improve the functionality and expansion of technological capabilities.

This problem is solved by providing the transducer with a range of resonant frequencies, increasing the efficiency, creating a component of torsional vibrations on its radiating surface and increasing the diameter of its central hole.

To this end, in an ultrasonic magnetostrictive transducer, including a magnetic circuit composed of monolithic plates, each of which is formed by a central element in the form of a ring and at least three, mainly double-rod, half-wave elements located symmetrically around the periphery of the central element, in accordance with the invention, half-wave elements made with a displacement of their longitudinal axis relative to the geometric center of the magnetic circuit, and the central element is made with a ring width equal to second half-wave width of the rod member, each half-wave element is disposed so that the longitudinal axis of symmetry of one of its rods is tangent to the median circumference of the central body, the central body and the hole formed with a diameter which is determined by the relationship:

D = (KN / 3.14) -B,

where D is the diameter of the hole of the Central element, mm;

K is the coefficient of proportionality equal to (N-Z) or (N + Z);

H is the height of the rod, the longitudinal axis of symmetry of which is not tangent to the average circumference of the central element, mm;

In - the width of the rod half-wave element, mm;

N is the number of half-wave elements in the plate of the magnetic circuit;

Z is a series of numbers (0, 1, 2, 3).

The invention is illustrated in the drawing, which schematically shows (top view) the Converter of the proposed design.

The following is an example of a specific embodiment of the invention, not excluding other embodiments of the proposed Converter in the scope of the claims.

The transducer 1 is composed of magnetostrictive plates made with a central hole 2. The magnetic circuit of the transducer is formed by four half-wave elements, each of which consists of two rods 3 and 4 of equal length and two overlays 5 and 6, respectively, external and internal (in the drawing of the lower lining of the half-wave elements are shaded). The inner linings 6 of the half-wave elements having a trapezoidal shape form an annular element, which is an integral part of the magnetic circuit. The Central hole 2, the wall of which is the radiating surface of the transducer, is made with a diameter equal to (KN / 3.14) -B, which determines the length of the average circumference 7 of the ring-shaped element in magnitude, a multiple of the length of the rod, and therefore a multiple of half the length of the ultrasonic wave the material of the magnetic circuit, and optimally equal to KN. The half-wave elements are located radially symmetrically with respect to the central hole 2 and so that the axis 8 of one of the rods in each of the half-wave elements is tangent to the middle circle 7 of the annular element, and the axis of the other rod passes through the central hole. In this case, the half-wave elements are equipped with an excitation winding 9 and shielding gaskets 10 attached to the plates 5, i.e. to the outer ends of the converter. The field winding is laid on rods 3 and 4 and passes through a window 11 made in each of the half-wave elements.

The proposed Converter operates as follows.

The alternating voltage of the resonant frequency supplied to the excitation winding 9 from an ultrasonic generator, for example from UZG-2-10 (not shown in the drawing), excites longitudinal vibrations in the rods 3 and 4 of the half-wave elements. Due to the simultaneous excitation of the rods, the wall of the central hole 2, i.e. the radiating surface of the transducer 1 is periodically compressed and expanded, making complex vibrations consisting of radial and torsional components. The presence of a component of torsional vibrations on the radiating surface of the transducer is due to the fact that the resulting oscillations (see drawing) of two adjacent rods oriented one relative to the other at an angle of 90 degrees, i.e. belonging to different half-wave elements, folding, for example, at point "A", is directed at a certain angle relative to the wall of the Central hole. Acoustic energy is emitted by the transducer into the processing object only from the wall of the central hole 2, because on the outer ends of the half-wave elements are shielding gaskets 10 made of porous rubber.

The vibration intensity of the proposed Converter, due to the matching of the length of the average circumference of the annular element with the length of the rod of the half-wave element, is slightly higher than that of the known one (15-30 W / cm2), and at the same time, due to the different masses of the sections of the inner plates located above each of the rods of one half-wave element has a range of resonant frequencies, the value of which is 4-8% of the calculated frequency of half-wave elements.

The implementation in the proposed Converter of the Central hole with a diameter that differs in value from the value (KN / 3,14) -B, as well as the orientation of the axis of one of the rods of the half-wave elements not tangent to the average circumference of the ring-shaped element, reduces the radiation intensity, since in these cases the length of the average circumference (KN) of the annular element, which is a load for the rods and, in particular, for the rod whose axis is tangent to this circle, will not be a multiple of the length of the rod, i.e. the dimensions of the annular element will not be consistent with the length of the rod and, therefore, will not be resonant.

When manufacturing the proposed converter, it is necessary to take into account that the length of the average circumference of the ring-shaped element, in its values closely interconnected with the diameter of the central hole, should be a multiple of the length of the rod, and in the best case, be equal to KN, i.e. the value of the proportionality coefficient K must correspond to the number of half-wave elements (K = N) in the magnetic circuit of the converter. Deviation from the optimal length of the average circumference of the ring-shaped element in one direction or another by an amount multiple of the length of the rod, but not exceeding one or two lengths of the rod, does not affect the operation of the converter, while at K less than (N-2) , i.e. when K = N-3 or K = N-4, etc., the diameter of the central hole has an insignificant value that limits the possibility of using the converter, and at K exceeding (N = 2), i.e. when K = N + 3 or K = N + 4, etc., the radiation intensity decreases.

It is also necessary to take into account the fact that (to achieve the maximum effect in the converter’s functionality), the holes 11 in the half-wave elements should be made so long that their radius surface located closer to the center of the magnetic circuit is tangent to the outer circle (not indicated in the drawing) central annular element.

The number of half-wave elements of the proposed Converter is determined by its technological purpose and the required radiation intensity. It seems optimal to perform the converter with three to five half-wave elements and with a length of the average circumference of the ring-shaped element equal to (2-3; 4-5) N.

The proposed Converter, assembled from plates made of magnetostrictive alloy K-65, with a design frequency of half-wave elements equal to 19.5 kHz and at N = 5, has the following geometric dimensions: diameter of the central hole 80 mm; the length of the average circumference of the annular element 325 mm; package height 50 mm; core width 65 mm; lining width 65 mm; height of external overlays 25 mm; the height of the inner plates 25-65 mm.

A comparative analysis of the known and proposed converters shows significant advantages of the latter in terms of its functional and technological capabilities. So, the proposed converter has a somewhat (7-12%) high efficiency, has a torsional vibration component on the emitting surface, has a range of resonant frequencies and can be made with a hole whose diameter significantly exceeds (100 mm at N = 6) the maximum possible (78 mm) the diameter of the Central hole of the known Converter.

Information sources

1. Volosatov V.A. Ultrasonic treatment. L: Lenizdat, 1973, fig. 24a.

2. USSR author's certificate No. 227428, IPC B 06 V 1/08, 1962.

3. USSR author's certificate No. 884747, IPC B 06 V 1/08, 1981.

Claims (1)

An ultrasonic magnetostrictive transducer, comprising a magnetic circuit selected from monolithic plates, each of which is formed by a central element in the form of a ring, and at least three, mainly two-rod, half-wave elements located symmetrically on the periphery of the central element, characterized in that the half-wave elements are made with a shift of their longitudinal axis relative to the geometric center of the magnetic circuit, and the central element is made with a ring width equal to the width of the rod luvolnovogo element, each half-wave element is disposed so that the longitudinal axis of symmetry of one of its rods is tangent to the average circumference of the central element, the central element and the aperture formed with a diameter which is determined by the relationship: D = (KH / 3.14) -B, where D is the diameter of the hole of the Central element, mm; K is the coefficient of proportionality equal to (N-Z) or (N + Z); H is the height of the rod, the longitudinal axis of symmetry of which is not tangent to the average circumference of the central element, mm; In - the width of the rod half-wave element, mm; N is the number of half-wave elements in the plate of the magnetic circuit; Z is a series of numbers (0, 1, 2, 3).