RU2664667C2 - Electro-acoustic transducer with damping of radiating membrane - Google Patents

Abstract

FIELD: acoustics.SUBSTANCE: invention relates to acoustics, in particular to electro-acoustic transducers. Electroacoustic transducer with damping of the radiating membrane contains a housing with holes for the output of acoustic vibrations, inside which a radiating membrane with piezoelectric elements, connected conductors with a generator of electrical oscillations, is fixed around the periphery. Mutual arrangement of several piezoelectric elements from one or both sides on the radiating membrane fixed around the periphery on the elastic attachment is produced in such a way that the mechanical oscillations interact with each other. At low frequencies, the transducer is configured to in-phase addition of wavelengths and with the possibility of maximizing the amplitudes of oscillations in the radiating membrane, at medium frequencies, the transducer is configured to interact with the wavelengths between themselves with a phase shift and with the possibility of equalizing the amplitude-frequency characteristic due to the effect of phase damping of mechanical vibrations in the membrane, at high frequencies, the transducer is configured to interact with each other in antiphase with the possibility of preventing the occurrence of spurious resonant oscillations, as well as the possibility of reducing the nonlinear distortions.EFFECT: high sound quality.1 cl, 3 dwg

Description

The invention relates to electro-acoustic transducers that can be used in telephone capsules and broadband speakers with damping of the radiating membrane.

Known electro-acoustic transducer with damping of the radiating membrane (EPDIM), comprising a housing with holes for the exit of acoustic vibrations, inside of which is fixed a sound-generating unit with elastic mounting on the periphery and connected by conductors to a generator of variable electrical vibrations (US patent No. 4297537, H04R 7/26).

The technical drawback of the analogue is that a mechanical damper made of an elastic material limits only the maximum amplitudes of the mechanical vibrations of the emitting membrane and is not able to suppress spurious resonant vibrations in EPDIM, which negatively affects its amplitude-frequency characteristic and narrows the spectrum of emitted acoustic vibrations.

The closest to the claimed invention in terms of technical nature and the problem to be solved is EPDIM, comprising a housing with holes for the output of acoustic vibrations, inside of which a piezo block including a radiating membrane with elastic fastening along the periphery and connected by conductors to a generator of variable electrical vibrations is fixed (RU 2088045 C1, 6, H04R 17/00, 08.20.1997).

A technical disadvantage of the known EPDIM: a damper made of an elastic material, mechanically acting on a radiating membrane, excessively reduces the amplitude of its vibrations at high sound frequencies, which narrows the spectrum of emitted acoustic vibrations, which excludes the possibility of listening to high-quality musical compositions; the damper does not suppress completely spurious resonant vibrations in the radiating membrane, leading to nonlinear distortions; a damper having direct contact with the entire surface of the radiating membrane and subject to a change in its physical parameters due to inevitable aging under the influence of alternating deformations worsens technical characteristics over time, including coefficient of performance (efficiency), reduces the life of EPDIM.

Technical task: equalization of the amplitude-frequency characteristic of EPDIM in the entire spectrum of sound frequencies and providing a spectrum of emitted acoustic vibrations from 20 to 20,000 Hz for the ability to listen to high-quality musical compositions, the complete suppression of spurious resonant vibrations in the emitting membrane, reducing non-linear distortion, increasing efficiency and increasing the term EPDM services. According to the invention, the electro-acoustic transducer with damping of the radiating membrane contains a housing with holes for the output of acoustic vibrations, inside of which a piezoelectric unit is mounted, including a radiating membrane with elastic fastening on the periphery and piezoelectric elements connected by conductors to a generator of variable electrical vibrations. The radiating membrane is equipped on one or both sides with piezoelectric elements interconnected by conductors in series or in parallel, depending on the choice of the amplitude of the emitted acoustic vibrations and the required impedance.

In FIG. 1 shows EPDIM, a general view in an axisymmetric vertical section along line AA (according to FIG. 2). It contains a housing 1 with acoustic holes 2, a piezoelectric block 3 including a radiating membrane 4 with elastic fastening along the periphery 5, electric oscillations of variable frequency are fed to the piezoelectric block 3 by conductors 6 from an alternating electric oscillation generator 7, the radiating membrane 4 of the piezoelectric block 3 is equipped with several piezoelectric elements 8 (they can be installed on the other side), interconnected in series or in parallel.

In FIG. 2 (bottom view of the radiating membrane 4) shows the location of four (there may be a different arrangement and other number) piezoelectric elements 8 on the radiating membrane 4.

In FIG. 3 shows a graph of the amplitude-frequency characteristics of the EPDIM depicted in figures 1 and 2.

In the initial state, FIG. 1, electric oscillations are not fed to the piezoelectric elements 8 via conductors 6 from the generator of alternating electric oscillations 7, and EPDIM does not emit acoustic vibrations.

EPDIM works as follows.

From the generator of variable electrical vibrations 7, electrical vibrations with a frequency of 10 Hz to 30 kHz are transmitted through the conductors 6 to the piezoelectric elements 8, which excite mechanical vibrations in the radiating membrane 4, the wavelength of which is comparable with the frequency of the supplied electrical vibrations.

At low frequencies, the wavelengths of mechanical vibrations from the piezoelectric elements 8 are maximum, and when interacting in the radiating membrane 4, they are in-phase added, increasing the amplitude of the vibrations of the radiating membrane 4, which leads to an increase in the amplitude of acoustic vibrations at low sound frequencies from 20 to 1000 Hz. This can be seen in the graph of the amplitude-frequency characteristic (AFC) - FIG. 3.

At medium frequencies, the wavelengths of mechanical vibrations excited by the piezoelectric elements 8 in the radiating membrane 4 interact with each other with a phase shift, which corrects the resulting oscillation amplitude and helps to equalize the frequency response at frequencies from 2 to 10 kHz - FIG. 3.

At higher frequencies, the mechanical vibrations excited by the piezoelectric elements 8 in the radiating membrane 4 interact mainly in antiphase, which prevents the occurrence of spurious resonances in the radiating membrane 4 and reduces non-linear distortions.

In the described “phase damping” modes (let's call these modes) the emitting membrane 4 excites acoustic vibrations in a wide range of frequencies from 20 Hz to 20 kHz with good frequency response - FIG. 3.

Thus, due to the fact that in EPDIM the radiating membrane 4 is provided on one or both sides with several piezoelectric elements 8 connected in series or in parallel, which together provides phase damping of the amplitude of mechanical vibrations in the radiating membrane 4, the amplitude-frequency characteristic of EPDIM is equalized in the entire spectrum of sound frequencies; a spectrum of emitted acoustic vibrations from 20 to 20,000 Hz was obtained (and higher - Fig. 3), which made it possible to listen to high-quality musical compositions; spurious resonance oscillations in the radiating membrane 4 are completely suppressed and, therefore, nonlinear distortions are reduced; improved efficiency and longer life of EPDIM. During the experiments, a spectrum of emitted oscillations from 20 Hz to 30 kHz with good uniformity of frequency response was obtained, which allows the invention to be used at ultrasonic frequencies as well.

Claims (1)

An electro-acoustic transducer with damping of the radiating membrane, comprising a housing with holes for the exit of acoustic vibrations, inside of which a radiating membrane with piezoelectric elements connected by conductors to an electric oscillation generator is fixed on the periphery, characterized in that the relative position of several piezoelectric elements on one or both sides of the radiating membrane, fixed around the periphery on an elastic mount, made in such a way that the mechanical vibrations of the wavelengths excited by them in a radiating membrane in a wide spectrum of frequencies they interacted with each other, while at low frequencies the converter is capable of adding in-phase wavelengths and maximally increasing the oscillation amplitudes in the radiating membrane; at medium frequencies, the converter is capable of interacting with each other with a shift in phase and with the ability to equalize the amplitude-frequency characteristics due to the effect of phase damping of mechanical vibrations in the membrane at high frequencies The transducer is made with the possibility of interaction of wavelengths with each other in antiphase with the possibility of preventing the occurrence of spurious resonant oscillations, as well as the possibility of reducing non-linear distortions.

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