DE1105210B - Electromechanical transmitter for high-frequency pressure waves in flow media - Google Patents

Description

GERMAN

The invention relates to electromechanical transmitters for generating and receiving sound waves in fluids. The term "sound waves" is intended to be waves with frequencies both above of the listening area as well as within it.

Electromechanical transmitters that are used for sound and ultrasonic frequencies under water, are known and generally consist of a solid, electrically sensitive material, the expands and contracts when subjected to an alternating magnetic or electric field and which has mechanical resonance at its operating frequency or is close to resonance. The so far The materials used are relatively rigid and vibrate with a very small amplitude, although they generate relatively large forces. They also have a high mechanical sound resistance which differs from the acoustic resistance of liquids. With direct coupling to the liquids they have an undesirably low transfer efficiency.

Because with transmitters a perfect adjustment of the sound wave resistance with mechanically on resonance working transformers is generally undesirable, but here the efficiency of the conversion the electrical energy within the transformer is reduced, the task is the mechanical Control resistance.

To solve this problem, there are already transmitters for high-frequency pressure waves in fluids become known where between an electromechanically sensitive, to expansion and contraction capable in the longitudinal direction, provided with an end face of the appropriate size and one arranged on the end face at a distance, a correspondingly large front work surface having a membrane that enables movement transformation and the body and the membrane connecting transmission member is arranged.

However, these transducers have the disadvantage that the membrane bends and not all of its sections vibrate together like a rigid part, because the membrane should be light and a perfect one Stiffness cannot be achieved.

This deficiency is eliminated according to the invention in that this transmission member has a plurality has side-by-side extending arms which merge into one another near their front ends and each of which extends from a largest cross-section at each end to a neck portion with • smallest 'cross-section tapers and each of these neck parts between the ends substantially Electromechanical transmitter

for high frequency pressure waves

in fluids

Applicant:

The Bendix Corporation,
New York, N, Y. (V. St. A.)

Representative: Dr.-Ing. H. Negendank _r patent attorney,
Hamburg 36, Neuer Wall 41

Claimed priority:
V. St. v. America May 5th 1954

Leon Walton Camp, Glendale, Calif. (V. St. Α.),
has been named as the inventor

closer to the front than to the rear end.

Further properties and advantages of the invention emerge from the description in connection with the Drawings of some embodiments.

It shows

Fig. 1 is a side view of a magnetostriction transducer,

Fig. 2 is a side view of Fig. 1, seen from one of the two sides,

Fig. 3 is a section along the line III-III of Fig. 1,

Fig. 4 is a side view of another embodiment of the horn,

Fig. 5 is a side view of Fig. 4, seen from one of the two sides,

Fig. 6 is a section along line VI-VI of Fig. 4,

7 is a schematic diagram showing a Represents a plurality of units according to FIG. 1 for sonication cleaning, and

8 is a schematic diagram showing the use of a plurality of transmitter elements in represents an underwater transmitter.

In Figs. 1 and 2, a transmitter element 10 is shown, which has an electromechanically responsive Has body 11, the end face of which Ho with the rear end of a transmitting the movements Member 12 is connected, the front part of which is a sound-absorbing or sound-radiating membrane or wall 13 represents.

109577/105

The body 11 is, as shown, a magnetostriction oscillating body consisting of nickel lamellas 11 b with an alternating current winding 14 and a direct current bias winding 15. The magnetostriction oscillating body can be coupled with its end face 11 α directly to the sound transmission medium.

The movement transmitting member 12 is preferably made of metal and can be directly attached to the Surface 11 α be soldered or welded so that it is firmly connected to it.

The member 12 is longitudinally divided into two arms or horns 12 a, 12 a, which have a rectangular cross-section over their entire length (Fig. 3), but gradually taper from a largest cross-section at a neck located near the forehead part. Before this neck portion each arm, however, is continuously expanding very rapidly to the membrane or wall 13 which has only a slightly smaller cross sectional area than the area 11 α, such as voltage from the drawing can be seen.

With the structure shown in FIG. 1, different types of vibrations can be determined as a function reach from the excitation frequency.

A magnetostriction element corresponding to element 11 is, as it is usually for a single Application is intended to run as long as half the wavelength; Under these conditions it vibrates with the greatest possible movement at its opposite ends and with one smallest Movement in a plane between the ends.

Likewise, if the total length of the transducer 10 from plane R of the rear surface to plane U of the end face is half a wavelength, the element will undergo maximum movement at its ends and minimal movement in a plane between its ends. This is its lowest or base working frequency.

One advantage of this design is that the transformer works effectively even at twice the basic frequency; under these conditions the total length of the transmitter is one wavelength. If the total length is one wavelength, the maximum movement occurs at the outer ends in the planes R and U and in a plane T located in the middle, and the minimum movement occurs in two between the planes R and T and T and U , respectively Levels.

It should also be noted that it is possible that the body 11 and the transmission member 12 is provided with four horns or arms 12 b instead of two. The increase in the number of arms results in a better distribution of the driving force on the front wall and facilitates the in-phase oscillation of all sections of the front wall. The extent to which the arm is subdivided depends in each particular case on the wavelength or frequency used and on the area of the membrane.

Fig. 7 shows an arrangement of transmitters according to the invention for cleaning a plate, e.g. B. a large glass plate. In the present case, the plate 19 is shown schematically on a number of Transmitters 10 passed, each of which has a motion converter, about the one members 12 shown in Figures 1, 2 and 3 is similar. The vibration surfaces 13 of the transmitter 10 are arranged in a common plane very close to the path of movement of the plate 19 and in a Liquid 16 immersed on the plate. The liquid 16 can have intense pressure waves that clean cause the plate to be granted.

In such a system, as shown in Fig. 7, the collaboration is between everyone End wall 13 and plate 19 are independent of the other, and it is not necessary that they be together be in phase.

Fig. 8 shows the application of the invention to an underwater transmitter. Here are a plurality of Elements 20 arranged in a row within a housing 17, this housing 17 having a sound window 18 has, against which the end walls 13 of the elements 20 bear.

In this example, each element 20 is shown as a titanium-containing ceramic body 21 with its End face is brought into connection with a movement-converting member 22, the body 21 is broadly similar in shape to member 12 in FIG.

The ceramic body 21 has a thinned central portion at its opposite one another Pages electrodes 23 are applied. The motion converting member 22 may be made of metal or a suitable one be non-metallic material with relatively good tensile stress and elasticity.

Since it may not be possible to create such a firm connection with a titanium-containing ceramic part how to produce with a metallic material, the vibrating element 20 can preferably with the Frequency of its first harmonic are excited, so that the connection between the body 21 and the transmission link 22 near the plane of least stress, i.e. H. comes to rest in a vibration node.

Since the end walls 13 are connected to the sound window 18 the units or elements 20 are partially supported by the end walls. An additional Support can be provided by a frame 24 in the housing on which the transmission links 22 are attached in or near their nodes of vibration. This can be done on the transmission links 22 flanges or ears 25 can be formed and fastened to the frame 24 by means of screws. The electrodes 23, 23 of each element are shown parallel to those of the other elements switched and connected to the conductors of a cable 26.

Claims (6)

Patent claims: 1. Electromechanical transmitter for high-frequency pressure waves in fluids, at that between an electromechanically sensitive, to expansion and contraction in Longitudinally capable body provided with an end face of the appropriate size and one arranged at a distance from the end face, a correspondingly large front work surface having a membrane, a movement conversion enabling and the body and the membrane connecting transmission member is arranged, characterized in that this transmission member has a plurality of them side by side extending arms (12 α) which merge into one another in the vicinity of their front ends and each of which extends from a largest cross-section at each end to a neck portion tapers with the smallest cross-section and that each of these neck parts between the ends essentially union is closer to the front (13) than to the rear end. 2. Transmitter according to claim 1, characterized in that the arms (12 a) in one piece are formed and merge into one another near their rear ends. 3. Transmitter according to claim 1 and 2, characterized in that the body (11), the end wall (13) and the arms (12 a) consistently have a rectangular cross section. 4. Transmitter according to claim 1 to 3, characterized in that both the length of the body (11) and that of the transmission element (12) are a quarter of the wavelength of the working frequency. ίο 5. Transmitter according to claim 1 to 4, characterized in that both the length of the body (11) and that of the transmission element (13) are equal to half the length of the working frequency. 6. Transmitter according to claim 1 to 5, characterized in that the neck portion of each Arm about an integral multiple of half a wavelength from the rear end of the electromechanically sensitive body and by essentially less than a quarter Wavelength from the end wall (13) is removed. Tn considered publications:
U.S. Patent No. 2,580,716;
French patent specification No. 931 945. 1 sheet of drawings