DE2908115C3 - Electrodynamic loudspeaker - Google Patents

Description

The invention relates to an electrodynamic loudspeaker according to the preamble of the patent claim 1.

Modern amplifiers hardly influence the transmission properties of a communication channel any more perceptible way. On the other hand, it is still true that the loudspeaker is the weakest link of the chain of transmission.

In order to improve the quality of the sound reproduction, so-called reusable boxes have been developed which one loudspeaker each for certain frequency ranges exhibit.

For the reproduction of the mid and high frequency range through such multi-way boxes are currently almost only systems with outwardly curved domes are used. These domes consist of thin fabric that is provided with a damping agent (see. US-PS 33 28 537; DE-PS 5 92 373; GB-PS 7 09 397; GB-PS 7 87 424; DE-PS 6 26 465).

Plate-shaped membranes made of polystyrene are also used to reproduce the low to midrange or known from the somewhat softer polyethylene. Their advantage lies in the possible flat construction, but they have so far not been able to assert themselves due to a lack of quality.

The invention is based on the object of creating a loudspeaker system that has a frequency range includes, which so far only includes at least two speaker system ^ and a crossover network could be.

This object is achieved according to the characterizing part of claim 1.

The advantage achieved by the invention is in particular that, despite the broadband Emission of sound signals a very low specific pressure load on the sound emitting device Material occurs. In addition, there are transit time differences that lead to partial cancellation of the sound pressure can only occur at very high frequencies. The Doppler effect can practically be neglected.

An embodiment of the invention is shown in the drawing and will be described in more detail below described.

The single figure shows the essential parts of a mid-range and tweeter according to the invention in section.

A spacer ring 2 is fitted in a baffle 1, which is provided with a front centering device 3 and a rear centering device 4 is provided. The front centering device 3 is with the front Part of a radiating body 5 connected, which carries a damping ring 6, while the rear centering device 4 is connected to a rigid paper tube 7 or the like, which in turn is firmly on the outer circumference of the radiating body 5 rests.

This paper tube 7 contains at the rear end a drive coil 18 which is wound onto the paper tube 7, this coil 18 can move in an air gap of a magnet 8, which consists of several Individual components 9 to 12 consists, of which with 5 the front pole plate, with 10 the magnetic ring, with 11 the is designated rear pole plate and with 12 of the pole core. The magnet 8 is closed by a cover 13 and in this way contains a cavity 14. This cavity can be provided with a damping means be filled out. Between the front pole plate 9 and the spacer ring 2 is a connection by means Screws 15, 16 manufactured by IH.

Essential for the present invention is the formation of the radiating body 5 from one Harl foam and a funnel-shaped cavity

ment 17, which in the figure as a quasi-parabolic Curve with the radiating surface 19 can be seen through the cavity 17 is a from the drive to the front boundary or towards the center of the radiator, the cross-sectional shape of the radiator body decreases sharply 5, so that because of the small mass in the middle, only little force is transmitted into this area got to.

The formation of disruptive pressure waves therefore only begins at higher frequencies.

The radiating body 5 is expediently made from a hard foam.

Compared to the known soft domes, a radiating body made of hard foam is suitable for radiation up to twice the frequency if it is suitably shaped. Although the relatively brittle material in the uppermost frequency range does not drop as smoothly as with a strongly self-damped dome, this is hardly a problem if the jumps are above 20 kHz, especially since there is hardly any difference in the phase response until then Kalotter can be determined.If the radiating body is formed according to the figure, an upper limit of at least 20 kHz and a sufficient load capacity to utilize a lower limit frequency of about 300 Hz are achieved with a diameter corresponding to the usual magnetic core size of 37 mm. The rigid foam used has Although a good ratio of strength to weight, this also leads to flexural vibrations of the center against the edge, the first resonance of which is far urn when the material is thin; 1OkHz can be. It is therefore necessary to approximate the thickness of the disc to the diameter. Taking the weight into account, a compromise thickness of 20 mm can be chosen. If a rigid foam of 50 kg / m ² is used, the first resonance then occurs at around 13 kHz. Given the high spring force of the material, this resonance would only be able to be reduced with an increase in weight by means of damping material, which would interfere with the efficiency. Because of the power losses in the radiating body 5, such a large mass at the end of the power transmission path would also impede the height transmission.

According to the invention, therefore, the thickness of the radiating body 5 is reduced towards the center, so that a cross-sectional shape is obtained in which the decrease in the moment of inertia only increases with the decrease in weight something is linear. This cross-sectional shape is particularly advantageous because of the shortening of the distance between the drive and the center of the radiating surface, which has a uniform running time and a better one Coupling of the central radiating surface with the drive brings

The distribution of the reactive forces is completely different in the case of the radiating body 5 in the upper frequency range at low frequencies. Spring and mass are then no longer spatially separated from one another, but the The clamping spring is practically ineffective as a reactive force, and the radiating body 5 is a structure made of homogeneous distributed mass, spring and friction damping. Therefore both pressure waves occur in the radiation body (between the drive and the radiating surface) as well as flexural waves (between the outside and the middle), which are overlay and together with reflections at the *> ■ "> Limitation of the body, but also by meeting equal amplitudes in the middle, standing waves can form. At the amplitude exaggeration in the middle part of the radiator it should be, after the Phase difference close to the beginning of a standing wave up to 1/4 or 1/3 wavelength (from outside to the middle), at least if the cant is broadband A broadband cant in the The center of the radiator is desirable in the upper frequency range because it acts on the otherwise increasing concentration opposite. It also improves the relationship between reactive energy consumption and radiated power, because the large masses (voice coil, edge area) that are not or only slightly involved in the radiation need to be accelerated less compared to the light, but high-amplitude center. The one from here However, the resulting profit does not appear to the outside world, because it is used to cover losses In the upper area, apart from the loss due to the phase, due to the deformation of the radiating body arise. As the frequency increases, larger parts of one form on the radiating surface Wavelength or several waves. the end. If more than 1/2 However, the wavelength of the drop is so great that the radiating body is no longer suitable for sound pressure reproduction suitable

Whether the hollow cone of the radiator is on the front or the magnet side is up to his internal behavior irrelevant. But if you include the drive, then the side with the big one has to Be assigned to the wall cross-section of the voice coil, because the wall cross-section which decreases towards the front reduces the force that is transmitted to the front end of the radiating body due to the decreasing mass must be, and thus the remaining longitudinal elasticity is less troublesome.

From around 10 kHz downwards, the radiating body can be viewed as a bulb. If there anyway Ripples in the sound pressure result, this is due to the front centering 3, which is outside the Attachment to the radiating body 5 no longer moves in phase with the piston at all frequencies, so that (The sound pressure it generates changes with changing Intensity, or even with an alternating sign, added to that of the piston. The one on the radiation involved area of this centering 3 should therefore be kept as small as possible, d. H. the centering 3 should be as narrow and deeply drawn as possible and made of sufficiently soft material.

Because of the greater amplitude that the system has at a diameter of 37 mm compared to a A mid-tone dome with a diameter of 50 mm and because of the length of the radiating body, it is sufficient nichi to only center it at one end or in the middle. Except for the front centering 3 am The front end of the body 5, which must be airtight, is therefore still a rear centering 4 provided, as close to the voice coil as the maximum stroke allows. This centering 4 can consist of the usual air-permeable fabric. Through these two at a distance of about 20 mm arranged centerings, the radiating body receives an axial largely free of tilting movements Guide.

The lower system resonance could with a good axial guidance of the oscillation system at 250 Hz or still under it. When using this area, the width of the magnetic field would also have to be corresponding be dimensioned, which means higher magnet costs or poorer efficiency. Because of the It does not appear expedient to increase the load

Operate the system at such low frequencies / u. the Resilience of a voice coil is to a large extent dependent on the possibility of convection, i.e. H. through the Determines the intensity of the air movement in the gap. Compared to a 50 mm system, the Voice coil of the 37 mm system with the same efficiency with 1.8 times the speed and is therefore better cooled. This additional cooling is already through the takeover of the High frequency range used. Since a deeper natural resonance can hardly be exploited, however is hardly necessary for reasons of the transfer properties, it is expedient to set this to around 350 Hz placed.

The weight of the oscillating system and that of the compared 50 mm dome system are practical equal (2.2 grams). Since the diameters differ in the ratio 1: 1.35, they behave Äbsirariiiiäcneii uei bciucii systems such as ί. 1.8. Because of the linear relationships between sound pressure and radiation surface, acceleration and weight, that would have to be the case smaller system to be lighter by this ratio, so that there is a corresponding one with the same driving force Acceleration received in order to reach the sound pressure of the comparison system.

The radiating body 5, including the damping, weighs 1.15 grams and is thus lighter than a 50 mm dome with 1.5 grams. The rest is in the bonds, the proportional weight of the centerings 3, 4 and the paper cylinder 7. which surrounds the foam from the coil set almost to the front edge. The rigid foam is available in densities of 30, 50 and 70kg / m ^! offered. The strength increases slightly disproportionately with the density. but the moment of inertia increases with the cube of the material thickness, so that a thinner disk made of a correspondingly denser material loses its flexural strength. Conversely, a disk made of thicker and specifically lighter material gains flexural strength, but because of the increasing longitudinal elasticity, a higher cut-off frequency cannot be achieved with it. It should therefore be used materials that have an even better ratio of strength

') to show weight.

The system according to the invention manages with a smaller air gap. and is therefore better cooled, so that it can withstand a higher power consumption and thus requires less efficiency. The air gap

in usual Kalottensysteme can both because of the Tilting tendency with larger amplitudes due to the simple centering, as well as due to the lack of a dimensionally stable fastening of the voice coil hardly less than 0.7 mm. The double centering that

ι ', attachment of the voice coil on the stiff radiating body as well as the smaller diameter compared to the 50 mm system should, however, be the case with the described system still has an air gap of 0.6 to

[Mill V.I I

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The voice coil and the magnet parts would be about half that of the known systems reduced. The thermal conductivity of iron is about 2000 times better than that of static air, so that even with a tenfold increase in the air conductance value

_'5 due to the movement of the voice coil, the size of the air gap determines the heat transfer. If the heat transfer is 70 or 80% better, the after der Nor;. ·, permissible lower impedance limit can be used, especially the burden of the losses of the second

in switch not applicable. Together with the increase in the A significant part of the sound pressure increase that is still required is thus obtained.

There are additional costs for the system described

ij is given by the two centerings 3, 4 compared to a mid-tone dome system. On the other hand, the costs for the hard foam cylinder as an easy-to-work machine part are lower than for the dome, which requires coating and drying cycles,

^J "and tends more to scatter and reject.

1 sheet of drawings

Claims (12)

Patent claims: 1. Electrodynamic loudspeaker with a magnet, a voice coil and a radiator, characterized in that the radiating body (5) has a base, a jacket surface and a radiating surface (19) and between these surfaces from a dimensionally stable Material is that a drive system (7; 18) at> ° the radiating body (5) engages and that all points of the radiating surface (19) about the same distance from the Line that is formed by the contact between the base and the lateral surface are removed. 2. An electrodynamic loudspeaker as claimed in arrival ^{| 5} entitlement 1, characterized in that the radiating body (5) is cylindrical and aufwcüt on one side surface a funnel-shaped recess (17) 3. Electrodynamic loudspeaker according to claims 1 and 2, characterized in that the cylinder jacket of the radiating body (5) is surrounded over a large area with a rigid coil carrier (7) is. 4. Electrodynamic loudspeaker according to claim 1, characterized in that the radiating body (5) is provided with 7 two centerings (3, 4). 5. Electrodynamic loudspeaker according to claims 1 and 4, characterized in that in a spacer ring (2) is provided on a Schaüwand (1) is, on which the radiating body (5) supporting centerings (3, 4) are attached. 6. Electrodynamic loudspeaker according to claim 1, characterized gekennzeici.net that the magnet (8) a front pole plate (9), a rear pole plate (11), a magnetic ring (10) and a pole core (12) having, wherein the pole core (12) is pierced. 7. Electrodynamic loudspeaker according to claims 1 and 6, characterized in that the spacer ring (2) is connected to the front pole plate (9) by means of screws (15, 16). 8. Electrodynamic loudspeaker according to claims 1 and 6, characterized in that on the rear pole plate (11) a cover (13) is provided, which the cavity (14) of the pole core (12) seals tightly. 9. Electrodynamic loudspeaker according to claim 8, characterized in that in the Cavity (14) a damping means z. B. cleaning wool is provided. 10. Electrodynamic loudspeaker according to claim 1, characterized in that the radiating body (5) is made of rigid foam with a high strength-to-weight ratio. 11. An electrodynamic loudspeaker as claimed in claim 1. arrival ^, characterized in that the radiating body (5) is provided with a damping ring (6). 12. Electrodynamic loudspeaker according to claims 1 and 2, characterized in that the funnel-shaped recess (17) is provided on the sound ^Μ emission side.