DE3337963A1 - Loudspeaker - Google Patents

Abstract

The loudspeaker comprises a magnet, an oscillating coil disposed in the annular gap of the magnet and a diaphragm which is held by a centring diaphragm attached to the magnet or to a frame permanently connected to the magnet, and to which diaphragm the oscillating coil is permanently connected by means of an oscillating coil support. The loudspeaker is characterised in that the oscillating coil support is designed at least partially as a screen through which radiation cannot pass and which has at least one aperture, the apertures being set apart from one another in the oscillation direction and/or in the circumferential direction of the oscillating coil support, at least one radiation source being disposed on one side of the oscillating coil support and at least one radiation receiver being disposed on the other side of the oscillating coil support and the radiation receiver(s) being located within the oscillation range in front of one aperture in the one direction of deflection and in front of the other aperture in the other direction of deflection. The loudspeaker enables extensive correction of non-linearities without a mechanical tap from the oscillatory system and without generating a monitoring voltage by means of an auxiliary coil connected to the oscillatory system.

Description

The invention relates to a dynamic loudspeaker with a magnet, a voice coil arranged in the annular gap of the magnet and a membrane which is held by a centering membrane attached to the magnet or a basket fixedly connected to it and with which the Voice coil is firmly connected by a voice coil former.

Loudspeakers of the type mentioned can only be regarded as a linear transmission system to a limited extent. Nonlinear Distortions result inevitably from the inhomogeneity of the magnetic field at the edges of the annular gap, the non-linearity of the mechanical restoring force the membrane suspension and through the air cushion enclosed behind the membrane. One tries to avoid these undesirable influences by choice a strong magnet and suitable shaping of the edge beads of the membrane and the centering membrane, but there are limits here. The use of stronger magnets, for example, has a negative effect on the costs and weight of the loudspeaker.

The invention is based on the object of creating a dynamic loudspeaker which largely compensates for the non-linearities allowed. In particular, this compensation should be without mechanical tapping from the oscillatory system and without generating a Control voltage through an auxiliary coil connected to the oscillating system be possible so that no mass influence occurs or by crosstalk only low values of the negative feedback are possible.

According to the invention, this object is achieved in the aforementioned loudspeaker in that the voice coil former is at least tail-

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wise than radiopaque, having at least one pinhole Screen is formed, the pinhole diaphragms in the direction of oscillation and / or in the circumferential direction of the voice coil former are spaced apart, - ' on the one hand the voice coil former has at least one radiation source and on the other hand the voice coil former has at least one radiation receiver is arranged and the or the radiation receiver within the Oscillation range in one direction of deflection next to the one pinhole and in the other direction of deflection next to the other pinhole are located. The oscillation movement is thus scanned purely by optical means on the voice coil former, so that no changes whatsoever are made to the mechanical vibration system are required. Any electromagnetic wave radiation can serve as radiation. The mechanical ones are located The vibration system in the rest position are the radiation receiver (s) shielded by the voice coil former so that no radiation from the radiation source is incident on them. The mechanical oscillation system becomes sound oscillations through an alternating current in the voice coil When excited, the apertured diaphragms alternately give the incidence of radiation on the radiation receiver (s) freely. The radiation source is a matter of course arranged in such a way that their radiation falls on the receivers when released through the apertured diaphragms, e.g. source and receiver are in a small amount Distance from the coil carrier arranged opposite one another. At two Radiation receivers falls due to their arrangement relative to the pinhole diaphragms When the voice coil former is at rest on one receiver, there is always only radiation when the system swings out to the same side. the Radiation receivers, which can be designed as transducers or conductors, then deliver signals proportional to the deflection, which are used for readjustment can serve the audio-frequency voltage on the power amplifier. COPY

According to one embodiment of the invention, the radiation source is a light source or the end of at least one light supplying device Optical fiber and the radiation receiver is a photodiode or the light receiving end of an optical fiber led to a photodiode. To In a preferred embodiment, the radiation source (s) are infrared emitters and the radiation receiver (s) infrared sensors or converters. To achieve the highest possible irradiance or illuminance on the radiation receivers or photodiodes and a radiation to keep behind light scattering is the radiation or light source Arranged as close as possible to the radio-opaque voice coil former. This goal can also be achieved by using the light source away from the voice coil former and directs the light through one or two optical fibers close to the voice coil former. Here there is the possibility of guiding the light only to the positions of the photodiodes located behind the coil carrier, so that the in the Idle position unwanted radiation through the pinhole diaphragms and interference from Radiation on the photodiodes is avoided. Analog can be done on the receiving end the vibrating point carrier radiation converters, e.g. photodiodes or corresponding infrared converters, or light-absorbing radiation conductors, in particular optical fibers may be provided which guide the radiation to remotely located photodiodes. In the first case, be immediate at the receiver audio-frequency current signals or in the working circuit of the photodiode of the deflection proportional, tapped currents or voltages generates »while in the second case the audio-frequency signals are only generated in the remote receivers can be converted into electrical control signals.

The radiation source is preferably arranged outside and the radiation receiver is arranged inside the voice coil former. A

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33379S3

any necessary replacement of the radiation source is with this one Arrangement easily possible. Appropriately, the outgoing control lines from the radiation receiver or radiation transmitter arranged within the voice coil carrier are passed through a bore in the pole core of the Magnet led. The lines are either one; Marian pair of leaders per receiver or transmitter, the part of the working circuit of the near the coil carrier arranged receiver or transmitter, or they are two optical fibers that are attached to two below the magnet or outside of the The receiver located in the loudspeaker.

According to the preferred embodiment of the invention, the perforated diaphragms are slots lying in the direction of oscillation of the coil former, the width of which is a function of the sensitivity of the radiation receiver. In particular, the slot width is also dependent on the respective Distance from the center line.

The inventive. Loudspeaker is described in more detail below with reference to the drawing. Show it

Figure 1 is an axial section of an embodiment of the loudspeaker in a simplified representation;

FIG. 2 shows a partial representation of an embodiment of the voice coil former in side view; and

Figure 3 is a partial representation of another embodiment of the voice coil former in the side view.

According to Figure 1, the magnet of the speaker consists of a

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Ferrite 1, an upper pole plate 1, a lower pole plate 1 and a pole core 1, wherein between the upper pole plate 1 ^a and the pole core 1, an annular gap 2 is formed in which a strong, substantially homogeneous magnetic field prevails. A basket 3 designed as a sheet metal or cast part is attached to the upper pole plate 1 ^{a by suitable methods.} A funnel-shaped membrane 4, e.g. made of thin cardboard, is suspended at its outer edge on the basket 3, while the inner edge of the membrane is firmly connected to a cylindrical voice coil carrier 5, e.g. made of plastic, aluminum or cardboard, which extends into the annular gap 2 protrudes. A centering diaphragm 6, for example made of fabric, with bead 6 ^a firmly connected to the inner edge of the voice coil bobbin 5 is attached to the outer edge of the basket 3 and, together with the rubber bead 4 ^a, ensures the ability to vibrate and centering of the diaphragm 4 and voice coil bobbin 5. The voice coil bobbin 5 carries at the end the voice coil 7, which protrudes from the annular gap 2 at both ends and whose connections for the audio-frequency alternating current are not shown.

Between the stepped lower side of the basket 3 and the upper pole plate 1 ^a , a socket 8 is attached at one point, in which a light guide cable 10 is fixed by means of an embedding compound 9. The light guide cable 10 is guided up to close to two perforated diaphragms 5 ^a , 5 of the voice coil former 5. At the end of the socket 8, a socket 8 ^a with a light source 11 is attached. Close to the two apertured diaphragms 5 ^a , 5, two photodiodes 12 ^a * are firmly mounted on the inside, the current-carrying lines 13 of which are guided to the outside through an axial bore 14 formed in the pole core 1.

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Figure 2 shows an embodiment of the perforated diaphragms 5 ^a , 5, which have the shape of triangular slots. The slots extend in the direction of oscillation X, one slot increasing in width in one direction of deflection and the other slot increasing in width in the other direction of deflection. The two receivers 12 ^a , 12 located behind the screen have the positions shown in broken lines in the rest position of the screen relative to the slots 5 ^a , 5, ie they are shielded from the radiation in the rest position of the voice coil former. When the vibratory system is excited, the slots 5 ^a , 5 open the windows of the photodiodes 12 ^a , 12, whereby audio-frequency light currents are incident and audio-frequency signals are available in the diode circuits that can be used to regulate the current in the power amplifier to avoid the non! Inearities of the oscillation system.

The coil carrier 5 according to FIG. 3 differs from that of FIG. 2 in that the two slots 5 ^a , 5 are arranged axially symmetrically to the center line M. In this case, a receiver 12 is provided centrally between the two slots 5 ^{a , 5, which alternately receives radiation through the slots 5 a} and 5. In the embodiment covered by the request for protection with a perforated diaphragm in the voice coil former 5, for example, the two triangular slots in FIG. 3 are brought so much closer together that they are combined to form a slot at the triangular tips. The narrowest point of this "double slit" then lies on the center line M.

In the preferred embodiment with scanning by means of infrared radiation, for example, a radiator of the type CQY 89A and a BPW 50 type detector is suitable (VALVO, Hamburg). In this version it is practical if the emitter and detector are located close to the slots,

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Claims (7)

speaker
Claims Dynamic loudspeaker with a magnet, a voice coil arranged in the annular gap of the magnet and a membrane which is held by a centering membrane attached to the magnet or a basket firmly connected to it and to which the voice coil is firmly connected by means of a voice coil former, characterized in that, that the voice coil bobbin (5) is at least partially formed as a radiopaque, at least one perforated ^{screen (5 a} , 5) having screen, the perforated diaphragms (5 ^a , 5) are spaced apart in the direction of vibration and / or in the circumferential direction of the voice coil bobbin, on the one hand the voice coil bobbin at least one radiation source (11) and on the other hand the voice coil support (5) at least one radiation receiver (12) is arranged and the radiation receiver (s) (12) are located within the oscillation range in one direction of deflection in front of one aperture plate (5 ^a ) and in the other Deflection direction in front of the other aperture plate (5). 2. Loudspeaker according to claim 1, characterized in that the radiation source (11) is a light source of suitable wavelength COPY I or the end of at least one light-supplying optical fiber (10) and the radiation receiver (12) is a photodiode or the light-receiving end of an optical fiber guided to a photodiode. 3. Loudspeaker according to claim 1, characterized in that the radiation source is an infrared radiator and the radiation receiver (12) is an infrared converter. 4. Loudspeaker according to one of claims 1 to 3, characterized characterized in that the radiation source (11) outside and the radiation receiver (12) are arranged within the voice coil former (5). 5. Loudspeaker according to one of claims 1 to 4, characterized characterized in that the radiation receiver (12) or radiation transmitter (11) which are arranged within the voice coil former (5) are outgoing Control lines (13) are guided through a hole (14) in the pole core (1) of the magnet. - · 6. Loudspeaker according to one of claims 1 to 5, characterized in that the perforated diaphragms (5 ^a , 5) are slots lying in the direction of oscillation (X), the width of which is a function of the sensitivity of the radiation receiver (12). 7. Loudspeaker according to one of claims 1 to 6, characterized in that the voice coil former (5) has two aperture plates (5 ^a and 6 ^b ). COPY