DE2908115A1 - Broadband loudspeaker with moving coil support - which is fixed to rigid cylindrical sound-radiating component - Google Patents

Abstract

The broadband loudspeaker has a rigid sound-radiating component (5) with a radiating face (19) equidistant at all points on its surface from the drive system (7). The radiating component is thin at its centre and thick at its periphery where the drive force is transferred to it. The radiating component is cylindrical and has a conical recess (17) in one side face. The cylindrical surface of the component is attached to the support holding the coil. The area of contact between support and cylinder is large. The radiating component has two centering pieces (3,-4) cooperating with spacing rings (2) fixed to the wall (1) through which the component projects. The band-width of the loudspeaker is equal to that obtained by two or more loudspeakers of previous design types.

Description

The invention relates to an electrodynamic loudspeaker

according to the preamble of claim L.

Modern amplifiers influence the transmission properties of a News channel in a barely perceptible way.

On the other hand, it is always true that the loudspeakers do are the weakest link in the transmission chain.

In order to improve the quality of the sound reproduction, so-called reusable boxes are available has been developed, each with a loudspeaker for certain frequency ranges exhibit.

For the reproduction of the middle and high frequency range through such reusable boxes systems with domed domes are currently almost exclusively used used. These domes are made of thin fabric that is covered with a dampening agent is provided (see US Pat. No. 3, 28.5) 7; DE-PS 592) 73; GB-PS 709,597; GB-PS 787,424; DE-PS 626 465).

For the reproduction of the low to midrange, there are also plate-shaped Membranes made of polystyrene or the somewhat softer polyethylene are known. Your advantage lies in the possible low-rise construction, but they have quality deficiencies so far not been able to enforce.

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

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

The advantage achieved with the invention consists in particular in that despite the broadband abstraction of tone signals a very low specific one Pressure load of the sound-emitting material occurs. In addition, there are runtime differences, which can lead to partial cancellation of the sound pressure, only at very high frequencies on. The Doppler effect can practically be neglected.

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

The single figure represents the essential parts of an inventive concept Middle and tweeter in section.

in a baffle 1, a spacer ring 2 is fitted with a front centering device 5 and a rear centering device N is provided is. The front centering device 5 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 rests firmly on the outer circumference of the radiating body 5.

This paper tube 7 contains a drive coil 18 at the rear end which is wound on the paper tube 7, this coil 18 being in an air gap a magnet 8 can move which consists of several individual components 9 to 12, of which with 5 the front pole plate, with lo the magnetic ring, with 11 the rear Pole plate and is designated with 12 of the pole core. The magnet 8 is covered by a cover 13 completed and in this way creates an airspace 14. This airspace can be filled with a dampening agent.

Between the front pole plate 9 and the spacer ring 2 is a Connection made by means of screws 15, 16.

The design of the separating body is essential for the present invention 5 which consists of a rigid foam and has a funnel-shaped cavity 17, which in the figure can be seen as a quasi-parsley-shaped curve with the radiating surface 19 is. Through this cavity 17 is a drive from the drive to the front boundary or given a strongly decreasing cross-sectional profile of the radiating body 5 towards the center of the radiator, so that because of the small mass in the middle only a little raft is transferred into this area must become.

The formation of disruptive pressure waves therefore only starts at higher fires a.

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

Compared to the known soft domes, a radiating body is made Rigid foam with a suitable shape up to twice the frequency for radiation suitable. It is true that the relatively brittle material is in the uppermost frequency range not as smooth a drop as to be achieved with a strongly self-damped dome, but if the jumps are over 20 kilz, this is hardly a problem, especially as well Until then, there was hardly any difference in the phase response compared to soft domes is. If the radiating body is formed in accordance with the figure, one achieves with one Diameter corresponding to the common magnetic core size of 57 mm is an upper limit of at least 20 kflz and sufficient load capacity to utilize a lower limit frequency of about 500 Hz. The rigid foam used, e.g. "Rohacell" made by RöhnX Darmstadt, although it has a good strength-to-weight ratio, but this also leads to bending vibrations of the center against the edge, the first of which Resonance with low material thickness can be far below lo kHz. It is therefore required to approximate the thickness of the disc to the diameter. Considering the weight can be chosen as a compromise a thickness of 20 mm. Using from Rohacell 51 = 50 kg / m the first resonance then results at around 15 kHz.

This resonance would only be with the great spring force of the material an effort to increase the weight which is disruptive with regard to the degree of efficiency to be reduced by damping material. Because of the power losses in the radiator 5, such a large mass at the end of the power transmission path would also reduce the height transmission hinder.

according to the invention, therefore, the thickness of the diffuser 5 is increased the center is decreased to give a cross-sectional shape in which the decrease of the moment of inertia with the decrease in weight only approximately linear. Particularly This cross-sectional shape is advantageous because of the shortening of the distance between the drive and the center of the radiating surface, which have a uniform running time and e better coupling of the central radiating surface with the drive.

The distribution of the blind forces is in the case of the radiating body 5 in the upper part Frequency range completely different from low frequencies. Spring and mass are then no longer spatially separated from each other, but the clamping spring is a reactive force practically ineffective, and the Abserahlkörper 5 is a structure of homogeneously distributed Mass, spring and friction damping have become. Therefore both occur in the radiating body Pressure waves (between drive and radiating surface) as well as bending waves (between outside and center), which are superimposed and together with reflections at the boundary of the body, but also when the same amplitudes coincide in the middle Can form waves. At the amplitude increase in the middle part of the radiator it is likely that, according to the phase difference, it is the beginning of a standing wave act up to 1/4 or 1/5 wavelength (from the outside to the middle), at least if the increase is broadband.

A broadband increase in the center of the radiator is in the upper frequency range desirable, because it counteracts the otherwise increasing concentration. You improved also the relationship between ß'lindenergi consumption and radiated power, because the large masses that are not or only slightly involved in the radiation (voice coil, Edge area) is less accelerated compared to the light, but high-amplitude center Need to become. However, the resulting profit does not appear outside in appearance, because it is needed to cover losses in the upper area, apart from the loss due to the phase, due to the deformation of the radiating body develop. With increasing frequency, larger parts form on the radiating surface one wavelength or several waves. At more than 1/2 wavelength, however, the drop is so great that the radiator is no longer capable of reproducing sound pressure suitable.

Whether the hollow cone of the radiator is on the front or the magnet is seldom is of no importance for its internal behavior. One relates but the drive must be included, then the side with the large cross-section of the wall must be the Voice coil be assigned, because the decreasing wall cross-section decreases towards the front because of the decreasing mass the Force applied to the front end of the Radiant body must be transferred, and thus the remaining longitudinal elasticity less annoying.

From about 10 kHz downwards, the radiating body can be viewed as X3wben earth. If there are ripples in the sound pressure anyway. is that up to the front Zentrlorung 5, which is outside the attachment to the Abstranlkörper 5 no longer moves in phase with the piston at all frequencies, so that of their generated sound pressure with changing intensity, or even with changing Sign added to that of the piston. The iläcne involved in the radiation this centering 5 should therefore be kept as small as possible, i.e. the centering 5 should be as narrow as possible and drawn deeply, and made of sufficiently soft material be made.

Because of the greater amplitude that the system has at a diameter of 57 mm compared to a mid-tone dome of 50 mm diameter, as well as Because of the length of the radiating body, it is not sufficient to only have it at one end or center in the middle. Except for the front centering 3 at the front end of the Body 5, which must be airtight, is therefore still centering at the rear 4, as close to the voice coil as the maximum stroke allows. This centering 4 can consist of the air-permeable fabric customary for this purpose. With these two centerings, which are about 20 mm apart, the Radiant body an axial guide largely free of tilting movements.

The lower system resonance could be with good axial contact of the Oscillation system at 50 Hz or even below. 3 when using this area the magnetic field width would also have to be dimensioned accordingly, which means higher magnet costs or means a poorer efficiency. Because of the increase in stress appears it is not practical to operate the system at such low frequencies. the The resilience of a voice coil depends to a large extent on the possibility of convection, i.e. by the intensity of the Air movement in the gap is determined. Compared with an Eo mm system, the voice coil of the 37 mm system moves with the same Efficiency at 1.8 times the speed and is therefore better chilled. This additional cooling is already due to the takeover of the Hocavon area claimed. Since a deeper natural resonance can hardly be exploited, however Also, if it is hardly necessary for reasons of the transfer properties, this becomes useful only placed about 350 Hz.

The weight of the oscillating system and that of the compared 50 mm dome system are practically the same (2.2 grams). Since the diameters are in a ratio of 1: 7 1.35 differ, the radiation surfaces of the two systems behave like 1: 1.8. Because of the linear relationships between sound pressure and radiation area, acceleration and weight, the smaller system would have to be lighter by this ratio, so with the same driving force a corresponding acceleration behaves by the Achieve sound pressure of the comparison system The radiating body 5 weighs inclusive Cushioning 1.15 grams and is therefore lighter than a 50 mm dome with 1.5 grams. However, its shape does not necessarily mean that it is optimally lightweight required Schwingvernalten. The eat is in the adhesions, the proportionate ewicnt the centering 3, 4 and the paper cylinder 7, which the foam from Coil set covered almost to the front edge. Rohacell is available in densities of 30, 50 and 70 kg / m are offered. The strength increases slightly but proportionally with the density to, but the moment of inertia increases compared to the material thickness with the third Potency, so that a thinner disk made of a correspondingly denser material in terms of flexural strength loses. Conversely, a disc that is thicker and therefore specifically lighter wins Although the material does not have flexural strength, it is because of the increasing longitudinal elasticity so that no higher cut-off frequency can be achieved. Materials should therefore be used which have an even better strength-to-weight ratio.

The system according to the invention manages with a smaller air gap, and is therefore better cooled, so that it can withstand a greater power consumption and thus less efficiency is required. The air gap of conventional spherical cap systems can both because of the tendency to tilt at larger amplitudes as a result of the simple Centering, as well as because of the lack of a dimensionally stable attachment of the voice coil hardly less than 0.7 mm. The double centering, the fastening of the Voice coil on the stiff radiating body as well as the opposite of your 50 mm Syst2m In contrast, smaller diameters should still have an air gap in the system described from 0.5 to 0.5 mm. The freedom of movement between 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 unmoved air, so that even with a tenfold increase in the air conductance the movement of the voice coil and the size of the air gap determine the heat transfer. at a 70 or 80 ß better heat transfer is then that permitted according to the standard lower impedance limit can be exploited, especially since the load caused by the losses of the second switch is omitted.

Together with the increase gained from the reduced air gap the efficiency thus becomes a significant part of the increase in sound pressure that is still required won.

Additional costs for the system described are compared to a mid-tone Kaiott system given by the two centerings 9, 4. Therefor are about the cost of the rigid foam cylinder as an easy-to-machine machine part, it will be lower than for the dome, the Painting and drying passages requires and thereby more to scattering and rejects tends.

Claims (1)

Electrodynamic full range loudspeaker claims 1. Electrodynamic Loudspeaker with a magnet, a voice coil and a radiator through it characterized in that the radiating body (5) is dimensionally stable and has a radiating surface (19), which in all parts is approximately the same distance from the drive system (7) is. 2. Electrodynamic loudspeaker according to claim 1, characterized in that that in the area of the takeover of the drive force of the radiating body (5) a relatively large one Material thickness, on the other hand in the outer area and in the middle of the radiating body (5) the material is relatively thin. 5. Electrodynamic loudspeaker according to claim 1, characterized in that that the radiation body (5) is cylindrical and on one side surface has a funnel-shaped recess (17). X. Electrodynamic loudspeaker according to claims 1 and 5, characterized Indicates that the cylinder jacket of the radiating body (5) with a stiff Coil carrier 7) is surrounded over a large area. 5. Electrodynamic loudspeaker according to claim 1, characterized in that that the radiating body (5) is provided with two centerings (5, 4). 6. Electrodynamic loudspeaker according to claims 1 and 5, characterized characterized in that a spacer ring (2) is provided in a baffle (1), to which the centerings (5, 4) carrying the radiating body (5) are attached. 7. Electrodynamic loudspeaker according to claim 1, characterized in that that the magnet (8) has a front pole plate (9), a rear pole plate (11), a Has magnet ring (lo) and a pole core (12), the pole core (12) being pierced through is. 8. Electrodynamic loudspeaker according to claims 1 and 7, characterized characterized in that the spacer ring (2) by means of screws (15, 16) with the front Pole plate (9) is connected 9. Electrodynamic loudspeaker according to claims-n 1 and 7, characterized in that a cover (13) on the rear pole plate (11) is provided, which seals the cavity of the pole core (12) tightly. lo. Electrodynamic loudspeaker according to Claim 9, characterized in that that a damping means z-.13 Putzwoile is provided in the cavity. 11. Electrodynamic loudspeaker according to claim 1, characterized in that that the radiating body (5) made of hard foam with a large strength-to-weight ratio consists. 12. Electrodynamic loudspeaker according to claim 1, characterized in that that the radiating body (5) is provided with a damping ring (6!) 15. Z-electrodynamic Loudspeaker according to Claims 1 and 5, characterized in that the funnel-shaped Recess (17) is provided on the sound radiation side.