DE2804499C2 - Electromechanical filter - Google Patents

Description

A = 038 L and Λ = 0.67 L
given area.

mechanical connection, such as by spot welding.
To generate damping poles, the additional coupling elements 9 and 10 are provided, of which the coupling element 9 is connected to the resonator 1 and the resonator 4, while the additional coupling element 10 is connected to the resonator 4 and the resonator 7

The torsion resonator 4 is in the arrangement according to F i g. 1 designed as a resonator with a circular cross section and has two symmetrical to its center arranged cross-sectional constrictions. Because of the for the bending resonator and for the torsion resonator

mutual distance of the respective longitudinal center of the cross-sectional constrictions (41, 42 ) to the total length L has a value of at least approximately AIl = 0.63.

2. Eiektromechanisches filter according to claim 1, 45 tor applicable different physical laws, characterized in that the ratio AI _L would otherwise result in general for the torsion resonator 4 compared to the bending resonators 1 to 3 or 5 to 7 greater length, because it it must also be required of the torsional resonator that its natural resonance lies in the pass band of the filter.
Since the torsion resonator 4 has two cross-sectional

has worked, it can die in the area of the center of the resonator

have the same cross-sectional dimensions as the bending resonators 1 to 3 or 5 to 7, which means that at the same time

The invention relates to an electromechanical filter 55 tig is possible, all coupling elements 8 to 10 in the next the preamble of claim 1. rich in the middle of the resonator at the individual resonators Such an electromechanical is to be attached in the main patent. This can be seen directly from Fig. 1, cal filter is indicated, the essential feature of which is that there are the additional coupling elements 9 is that to generate damping poles and 10 at the top of the individual resonators geder Filter characteristic in the course of the individual resonance leads, and it is the Koptors that determine the bandwidth at least one torsion resonator is provided, pelelement 8 on the opposite resonator attached to at least one of the additional coupling elements.

attacks. The installation of dumbbell-shaped torsion resonators

In FIG. 1 shows such an arrangement which emerges from the main patent in mechanical filters with flexural oscillators. It is the generation of arbitrary attenuation poles with a mechanical filter made up of seven resonance-simple, straight overcouplers.
gates, of which the resonators 1 to 3 and 5 to 7 are used as The natural frequency of a dumbbell resonator is low

Useful oscillation execute a bending oscillation. The ger than that of a vibrator with consistently the same

Cross-section By suitable choice of the cross-section jumps you can now with simultaneous agreement the natural frequency, the length of a dumbbell resonator can be adapted to the length of the flexural oscillator. aside from that the effective mass determining the coupling is influenced by these cross-sectional jumps The effective mass here is that mass which is comparable in terms of its vibration behavior Oscillator, the cross-sectional area of which is constant over the entire oscillation length

In the manufacture and in particular the subsequent final adjustment of such dumbbell resonators Now the difficulty arises that with the generally required retention of the overall length and diameter the adjustment of the dumbbell resonators only by correcting the dimensions of the cross-sectional constrictions can be made. Such a correction, for example of the diameter the cross-sectional constrictions can, however, in an undesirable manner, a strong dragging of the Coupling determining and determined by the neighboring resonators value of the effective mass of the resonator. Continue to yield .; with such dumbbell resonators as a result more unavoidable Manufacturing deviations with regard to the nominal dimensions undesirably large deviations in the effective mass and the resonance frequency from the setpoints established during the filter design.

The invention is therefore based on the object to avoid these disadvantages and a training of the Specify torsion resonators, due to the unavoidable manufacturing deviations on the one hand, only small deviations the effective mass and the resonance frequency result, and by the other hand a good adjustability with regard to the resonance frequency with simultaneous minimal change in the effective Mass is guaranteed

Based on the specified at the beginning electromechanical filter of claim, this object \ is achieved by the characterizing features

A particular advantage of the invention results from the economical simultaneous production of both cross-sectional constrictions by one tool, in which generally a very precise maintenance of the mutual center-to-center distance A of the cross-sectional constrictions can be achieved regardless of the wear of the workpiece. As a result of the unavoidable fluctuations in width of the cross-sectional constrictions that occur here, according to the invention, there is only a very small change in the resonance frequency and the effective mass.

A particularly advantageous embodiment of the invention results from a ratio of the center-to-center distance A of the cross-sectional constrictions to the total length L of at least approximately AI _L = 0.63. In this case there is a minimum of the dependence on width fluctuations of the cross-sectional constrictions for the effective mass as well as for the natural frequency.

The invention is explained in more detail below with the aid of exemplary embodiments. It shows in the drawing

1 shows an embodiment known from the main patent an electromechanical filter made of mechanical bending resonators with a two-dimensional constriction having torsion resonator.

F i g. 2 an embodiment of a dumbbell-shaped A torsion resonator with z * .ei cross-sectional constrictions, FIG. 3 shows the dependence of the resonance frequency and the relative mass as a function of the width of the cross-sectional constrictions for a / i torsion resonator,

F i g. 4 and 5 representations of the change in natural frequency and relative mass of a torsional resonator according to the invention.

In the embodiment according to FIG. 2 is a dumbbell-shaped yi torsion resonator, for example for a filter according to FIG. 1 shown The length L and the diameter D of the resonator is related to the length and the diameter of the other resonators of the filter according to FIG. 1 matched. Due to the cross-sectional dimensions that match the other resonators in the area of the resonator center, it is possible to fasten all coupling elements to the individual resonators in the area of the resonator center. The cross-sectional constrictions 4t and 42 are attached symmetrically to the center of the cylindrical torsion resonator in such a way that the resonator has two identical outer and one central parts each having the same diameter. .-: s contains.

In the exemplary embodiment, the width of the transverse constrictions is b and the mutual distance between the centers of the two cross-sectional constrictions 41 and 42 should have a value A. With a ratio of distance A to total length L between the values 0.58 and 0.67, the result for the dumbbell-shaped torsion resonator according to FIG. 2 shows a particularly small influence on the effective mass and / or the resonance frequency as a result of manufacturing deviations. Furthermore, the correction of the resonance frequency required during the final adjustment in such a resonator can be carried out by further reducing the diameter of the cross-sectional constrictions 41 and 42, without a simultaneous strong dragging of the effective mass and thus the coupling to the. neighboring resonators results. This is of particular importance because, in contrast to the natural frequency, the effective mass can only be measured or compared with relatively great effort.

Another advantage of the dimensioning according to the invention of the torsion resonator results from a particularly flat course of the effective mass as a function of the groove width, so that an adjustment option can also be made by changing the groove width given is. without the effective mass of the torsional resonator changing significantly.

In FIG. 3 is for a dumbbell-shaped torsion resonator of constant length L according to FIG. 2 shows the dependence of the resonance frequency and the relative mass on the width b of the cross-sectional constrictions. Here, the course of the natural frequency is shown in the form of continuously plotted curves for different center-to-center distances A of the cross-sectional constrictions from 8.5 to 12 mm. There is a minimum for each of these curves, which becomes flatter as the center-to-center distance A decreases. In the illustration according to FIG. 3, the course of the relative mass m / iTiB for such a dumbbell-shaped torsional resonator with tangential coupling in the center of the oscillator is again shown in dashed lines for various center-to-center distances A between 8.5 and 12 mm. The effective mass was determined after the natural frequency was kept constant by changing the diameter of the cross-sectional constrictions. This roughly corresponds to the required frequency adjustment, for example by removing material from the Einslich.

It can also be seen from FIG. 3 that the

The size of the effective mass can be influenced by the choice of the center-to-center distance A of the two cross-sectional constrictions. The course of the curves for the effective mass rn / rne shows that within the range of Al ₁ . between 0.58 and 0.67 for each center-to-center distance A with a particular width b of the cross-sectional constrictions results in a minimum, in the vicinity of which the sensitivity with regard to changes in the effective mass is particularly low.

A particularly advantageous dimensioning results from a ratio of the center-to-center distance A of the cross-sectional constrictions to the length L of the resonator of 0.63. With this dimensioning, there is a minimum of the dependence on the width of the cross-sectional constrictions for both the effective mass and the natural frequency. Such a case is shown in FIGS. 4 and 5 shown.

In detail, FIG. 4 for a dumbbell-shaped ^CT en "T ~ orsion ^c r £ son2tor der OeTisss'T ¹ " ^ -! ^ * 7 πγγϊ = 0.63 · L and the initial width b of the cross-sectional constrictions of 3.5 mm the change in Natural frequency as a function of a correction from the width b of the cross-sectional constrictions. F i g. For the same resonator, FIG. 5 shows the relative change in the effective mass after a frequency adjustment, likewise as a function of the width correction Ab of the cross-sectional constrictions. From the representations according to FIGS. 4 and 5, for the dimensioning of the torsion resonator given above, a change in the puncture width of 5.7% results in a change in the natural frequency of only 0.4% and a relative change in the effective mass of only 0.25%.

For this purpose 2 sheets of drawings
35

40

45

Claims (1)

Patent claims: 1. Electromechanical filter, in which several, parallel-axially arranged, rod-shaped mechanical bending resonators are provided, which lie next to one another in one plane and which are coupled to one another via at least one coupling wire that carries out longitudinal vibrations,
and in which the filter oscillation system additionally contains at least one torsion resonator, the resonance frequency of which, like the resonance frequencies of the bending resonators, lies in the filter pass band and which is coupled to the coupling wire connecting all of the bending resonators, and in which at least one additional coupling element serving to generate at least one damping pole is inserted into the filter oscillation system,
and where there are electrostrictive converting resonators at the input and output for converting electrical into mechanical or reconverting mechanical into electrical energy, and in which one end of the additional coupling element (9, 10) engages the Tbrsionsresonator (4), which is arranged in the filter oscillation system that its axis parallel to the axes of the direction of oscillation for a certain moment is indicated by the arrows 13 made. A torsion resonator is used as the middle resonator 4, the direction of oscillation of which is indicated at the same instant by the semicircular arrow 13 '. T ίο applied As from F i g. 1 can also be seen the bending resonators are provided with a flat, and the inner resonators are arranged in such a way that that this flattening runs parallel to the filter base plate 1Ϊ, while the end resonators 1 and 7 Γ5 flattening runs perpendicular to the filter base plate The individual resonators themselves consist of a metallic material and are about the metallic Support legs connected to the base plate 11, which is why the base plate 11 at the same time an electrical reference represents potential for the filter. The supply or removal of the electrical signal energy takes place in a known manner through a thin metallization applied to the electrostrictive plates Γ or T , to which the connecting wires are brought directly. The coupling of the individual resonators takes place via a continuous coupling wire 8, which itself Carries out longitudinal vibrations and which must be dimensioned in terms of its length and cross-section so that that the required bandwidth for the filter is achieved Flexural resonators (1-3 and 5-7) run according to Pa- 30den. The continuous coupling wire 8 is included tent 2607879, characterized with each of the resonators by a suitable medass '"'" ..._ .. an Ijrsionsresonator circular cross-section with two transverse constrictions (41, 42), which are symmetrical to the longitudinal center of the torsion resonator are arranged as a resonator is used, and that the central planes of the cross-sectional constrictions aligned perpendicular to the longitudinal axis of the resonator have a mutual spacing A which is within the range defined by the limits