DE864270C - Loudspeaker with conical membrane, not clamped at the edge - Google Patents

Description

Loudspeaker with conical membrane, not clamped at the edge It is known to train electrodynamic speakers so that the membrane is a cone that is clamped at its outer edge and near the tip is the moving coil wearing. It is also customary to place a centering on the moving coil, dir ensures that the plunger coil works exactly vertically so that it is not in the Air gap of the magnet grazes. The subject of the invention is now an arrangement in which the conical membrane is not clamped at its outer edge, but on this or another point contains a second or more centering.

This avoids disruptive influences from the hinge. To the For example, it is difficult for speakers with a small diameter to vibrate System tuned deep enough because the elastic forces of the hinge fail can be reduced to a certain extent. For pronounced woofers It is even common to use leather hinges which are not easy to obtain are. In addition, a large, soft hinge goes through a considerable part of the Membrane area for sound radiation is lost because the soft hinge is closed only little involved in sound radiation. It is also known that the individual grooves in the hinge tend to have resonances that are difficult to suppress are and also. attenuate particularly high frequencies. All of these drawbacks are avoided by the subject invention.

A freely oscillating conical membrane that is not clamped at the edge can be used to radiate such high frequencies without any further aids whose wavelength is smaller than the membrane diameter. At deeper Frequencies The difference in sound pressure in front of and behind the membrane would be caused by an acoustic short circuit be compensated without sound radiation, because now there is no hinge to hinge the sound insulates and connects the vibrating membrane with a surrounding baffle. A considerable However, sound insulation at the edge of the membrane is also possible in that the membrane from a hollow body, e.g. B. a, piece of pipe, is surrounded; where .the free distance of the membrane edge from the surrounding hollow cylinder irr - ratio to the membrane diameter would only have to be very small. This enables the membrane to vibrate freely there must be a measurable gap, but it can be design so that it is less than about 2% of the membrane diameter. Only a small part of it becomes through this circular scratch. Sound pressure difference can balance each other in front of and behind the membrane and in the! rest also a radiation lower frequencies are possible.

The hollow body surrounding the membrane can be a circular cylinder, and its axis mnü3 parallel to the movement of the diaphragm .be. The hollow body ex can also have a non-circular cross-section, e.g. B. be ieliptical if the vibrating membrane is also elliptical.

The figure illustrates this structure. a is a leash cone cap, With it moving coil, e i the lower centering, which is usually formed. This cone membrane now has another tensing id held by the pin! and is therefore an internal centering. The outer edge of the conical membrane is free moveable covenant works with a very small one. Air gap / within the Membrane surrounding pipe section g: Such an arrangement can be easily built, closed; so that it vibrates when the individual parts are so dimensioned are, 'that the pipe piece is just pushed over the round dimensions of the system can be. This means that the pipe section can be firmly attached and now also protects at the same time the vibrating system that surrounds it in all directions.

Behind the conical membrane a in the pipe section g there is now an air space i essentially; not hindered on all sides; the tube g receives a series of air holes k. The air holes can be so dimensioned that they are closed off together with the smoke Air volume i form a tuned Hehnholtz resonator around the frequency response , of the loudspeaker according to you influence.

Other electroacoustic devices can also be designed in the same way be. What has been said above for a loudspeaker applies in a similar way also for headphones and microphones.

Claims (7)

PATENT CLAIMS: i. Electroacoustic sound transducer, loudspeaker, Headphones or microphone, working according to the telectrodynamic principle, thereby characterized, @ that the membrane is not clamped at the outer edge and by two. or several centerings of a known type. 2. Sound transducer according to claim z, characterized in "that the edge of the membrane for sound insulation is surrounded by a hollow body, whereby the free distance of the Mernbran edge of this is less than 20/0 of the diaphragm diameter. 3. Sound transducer after Claim z, characterized in that the hollow body is a circular cylinder and its axis is parallel to the direction of movement of the membrane. q .. Sound transducer after Claim z, characterized in that the cross section of the hollow body is not circular, but z. B. is elliptical. 5. Sound transducer according to claim 2, characterized characterized da.ß the hollow body is a piece of pipe that over the round magnet systems is pushed. 6. Sound transducer according to claim z, characterized in that the ggekennzeichniet Hollow body 'is to be understood with air holes. 7. Sound transducer according to claim 6, characterized characterized in that the air holes with the closed air volume behind the Membrane form a tuned resonator.