EP0403378A1 - Omnidirectional loudspeaker with spherical diaphragm using a two-layer magnetostrictive ribbon - Google Patents

Abstract

The invention relates to an omnidirectional loudspeaker. This loudspeaker comprises a spherical membrane which comprises turns formed of a ribbon (2) of a magnetostrictive material wound spirally in a sphere; these turns are held by an elastic support (1), so that with the support they form a spherical membrane. The ribbon has two opposite faces (11, 12), one of which is directed towards the inside (I) of the sphere and the other towards the outside (E), and two ends (3, 4) located in two diametrically opposite zones of the sphere, to be connected to an electrical control means (5) supplying a signal corresponding to sound waves to be reproduced, and a means (7) for continuous polarization of the membrane. According to the invention, one of the faces (11) of the ribbon (2) is at least partially covered with a thin layer (13) of a rigid material. Application to the diffusion of high quality omnidirectional sound waves.

Description

The present invention relates to an omnidirectional speaker with a spherical membrane using a magnetostrictive bimetallic strip. This invention is applicable to the omnidirectional broadcasting of sound waves by means of a high performance loudspeaker, with wide bandwidth, extending throughout the range of audible frequencies.

An omnidirectional loudspeaker is known, with a spherical membrane, having a wide bandwidth and using the phenomenon of magnetostriction. This speaker is described for example in European patent application ^No. 0177383, filed August 22, 1985 in the names of the same applicants.

This patent application describes an omnidirectional elastic wave transducer with a large passband, and more precisely a spherical speaker using the phenomenon of magnetostriction.

In a particular embodiment described in this patent, the omnidirectional loudspeaker, of spherical shape, consists of a ribbon; of a magnetostrictive material wound in a spiral, an elastic seal joining the turns of the ribbon the two ends of this ribbon are connected to means for applying to the loudspeaker thus obtained, which forms a spherical pulsating membrane, a corresponding electrical control signal sound waves to broadcast. The two ends of the ribbon are located in two areas diametrically opposite of the pulsating membrane. This loudspeaker also comprises means of continuous and permanent magnetic polarization, for polarizing the pulsating membrane so that the acoustic wave has an amplitude proportional to the control signal applied to the ends of the ribbon.

The loudspeaker described in this patent has the drawback, however, of having only a low power at low frequencies; this imperfection is mainly due to the difficulty of obtaining a large amplitude of the pulsations of the spherical membrane at low frequencies.

The object of the invention is to remedy this drawback and in particular to produce a loudspeaker with a spherical pulsating membrane, ensuring sufficient acoustic power in all frequencies and more particularly at low frequencies. These aims are achieved in particular through the use of a magnetostrictive tape having at least one of its faces completely or partially covered by a thin layer of a material, such as copper, ceramic, etc.. The presence of this rigid thin layer gives the ribbon, as will be seen in detail below, the properties of a bimetallic strip, the deformations of which are not controlled by variations in temperature, but by the application of a current modulated electric control. This current causes variations in the length of the magnetostrictive tape which, subject to the stresses of the rigid thin layer, the length of which does not vary, deforms substantially at the rate of the variations in amplitude of the modulation current.

FIGS. 1a and 1b will make it possible to better understand the phenomenon of magnetostrictive bimetal strip used in the loudspeaker of the invention.

FIG. 1a is a side view of a portion of a magnetostrictive tape M, surrounded by a coil B. In the absence of electric current in the coil B, the tape M has a length L.

When a current is applied to the coil B, and in the absence of a permanent continuous magnetic field, the coil induces a magnetic field in the ribbon which shrinks and then has a length L1, very little less than L.

Figure 1b shows laterally the magnetostrictive ribbon M, surrounded by the coil B. This ribbon is here covered, on one of its faces, by a thin layer of a rigid material such as copper or ceramic for example. In the absence of current in the coil B, the ribbon M and the layer R have a length L.

When a current is applied to the coil B, and in the absence of a permanent and continuous magnetic field, the magnetostrictive tape M shrinks, but the mechanical stresses due to the presence of the rigid thin layer R secured to the tape M cause the curvature of the assembly which then has a length L2. The difference in length L-L2 is much larger than the difference L-L1. This phenomenon is comparable to that of a thermal bimetallic strip whose curvature is caused by temperature. Here the curvature is due to the shrinking of the magnetostrictive tape, subjected to the constraints of the rigid and non-magnetostrictive material of the layer R. The arrangement of FIG. 1b can be qualified as "magnetostrictive bimetal strip".

The invention uses this bimetallic strip in a spherical loudspeaker having sufficient acoustic power throughout the range of acoustic frequencies and in particular at low frequencies.

The invention relates to an omnidirectional loudspeaker comprising a spherical membrane, which comprises turns formed of a ribbon of a magnetostrictive material wound in a spiral according to a sphere, these turns being held by an elastic support, so that they form with said support said spherical membrane, this ribbon having two opposite faces, one of which is directed towards the inside of the sphere and the other towards the outside, and two ends situated in two diametrically opposite zones of the sphere, to be connected to an electrical control means supplying a signal corresponding to sound waves to be reproduced, and a means for continuous polarization of the membrane, characterized in that at least one of the faces of the ribbon is at least partially covered with a thin layer of rigid material.

According to a first embodiment of the loudspeaker of the invention, the ribbon is covered by the rigid thin layer on its face directed towards the outside of the sphere.

According to another embodiment of the loudspeaker of the invention, the ribbon has, over its entire length, transverse corrugations, each corrugation having on the face of the ribbon, directed towards the inside of the sphere, a concave zone and a zone convex and, on the face of the ribbon directed towards the outside of the sphere, a concave zone and a convex zone, the rigid layer being located at least partially on the face of the ribbon directed towards the outside of the sphere, opposite the convex areas of this face.

According to another embodiment, the ribbon has transverse undulations over its entire length, each undulation having on the face of the ribbon directed towards the interior of the sphere, a concave zone and a convex zone and, on the face of the ribbon directed towards the outside of the sphere, a concave zone and a convex zone, the rigid layer being located partially on each face of the strip, opposite the concave zones or opposite the convex zones.

According to another characteristic of the invention, the means for continuous polarization of the membrane is a permanent magnet located inside said membrane.

According to another characteristic, the DC biasing means is a DC voltage source connected to the ends of said strip.

According to another characteristic, said membrane is formed of two hemispheres joined to one another.

• - les figures 1a et 1b ont déjà été décrites et permettent de mieux comprendre le principe du bilame magnétostrictif ;
• - la figure 2 représente schématiquement un premier mode de réalisation d'un haut-parleur conforme à l'invention ;
• - la figure 3 représente schématiquement un autre mode de réalisation de ce haut-parleur ;
• - la figure 4 représente schématiquement une vue transversale d'une première variante d'un ruban magnétostrictif utilisé dans le haut-parleur de l'invention ;
• - les figures 5, 6 et 7 représentent schéma­tiquement des vues latérales de différentes autres variantes du ruban magnétostrictif utilisé dans le haut-parleur de l'invention.

The characteristics and advantages of the invention will emerge more clearly from the description which follows, given with reference to the appended drawings, in which:

• - Figures 1a and 1b have already been described and allow a better understanding of the principle of the magnetostrictive bimetal strip;
• - Figure 2 schematically shows a first embodiment of a loudspeaker according to the invention;
• - Figure 3 shows schematically another embodiment of this speaker;
• - Figure 4 shows schematically a transverse view of a first variant of a magnetostrictive tape used in the loudspeaker of the invention;
• - Figures 5, 6 and 7 schematically show side views of different other variants of the magnetostrictive tape used in the loudspeaker of the invention.

FIG. 2 schematically represents a first embodiment of an omnidirectional loudspeaker, according to the invention.

This loudspeaker comprises a spherical membrane which comprises turns (2) of a magnetostrictive tape, wound in a spiral according to a sphere. These turns are held by an elastic support 1 which can be either a hollow sphere of an insulating and elastic material, on which the turns are glued, or a strip of an elastic material wound helically according to a sphere, this strip being located between the turns and being made integral with these.

The tape 2 of magnetostrictive material forms with the support 1 a spherical membrane.

The ribbon has two opposite faces, one of which is directed towards the inside of the sphere, and the other towards the outside of the sphere. According to the invention, and as will be seen below in detail, the tape 2 of magnetostrictive material comprises on at least one of its faces an at least partial coating of a thin layer of a rigid material such as copper , ceramic ... etc. It also has two ends 3, 4, located in two diametrically opposite zones of the spherical shell 1. These ends are connected to a control means 5 providing a modulation signal corresponding to sound waves to be reproduced. This control means can be constituted for example, in this embodiment sation, by a transformer, a primary winding 6 of which receives the output signal from an amplifier. The secondary winding 7 of this transformer applies this signal to the ends 3, 4, of the ribbon 2. The loudspeaker also comprises a means of continuous polarization constituted here by an electric source 7 of direct voltage, one of the terminals of which is connected to the end 4 of the ribbon 2 and the other terminal of which is connected to the end 3 of this ribbon, via a choke L. A decoupling capacitor 9 also appears in the figure. This capacitor is conventional in the connection of a loudspeaker to the output of an amplifier. The DC voltage source induces a continuous and permanent magnetic field in the ribbon.

According to the invention, and as will be seen below in detail, at least one of the faces of the tape 2 has a rigid thin layer completely or partially covering this face. This layer does not appear in this figure and will be described later.

FIG. 3 schematically represents another embodiment of the loudspeaker of FIG. 1. The means for continuous polarization of the ribbon is here constituted by a permanent magnet 10 situated inside the spherical membrane. This permanent magnet, of cylindrical shape for example, has an axis common to the axis X of the loudspeaker. In this case, the DC voltage source 7, the choke L and the decoupling capacitor 9, are not necessary and the secondary winding of the transformer 5 is directly connected to the ends of the strip 2. According to the invention, at least l 'One of the faces of the tape 2 here also has a rigid thin layer completely or partially covering this face. This layer does not appear in this figure and will be described later.

Figure 4 is a schematic transverse view of an alternative embodiment of the magnetostrictive tape covered with a rigid thin layer, used in the loudspeaker of the invention. According to this variant, the magnetostrictive tape 2, which has two opposite faces 11, 12, one (face 12) directed towards the inside I of the sphere and the other (face 11) directed towards the outside E of the sphere, is completely covered on its face 11, directed towards the outside of the sphere, by a thin layer 13 of rigid material. The magnetostrictive tape can be constituted for example by a colbalt / nickel alloy, while the rigid thin layer 13 can be a layer of copper or a ceramic for example.

According to the polarity of the current applied to the ribbon made up of the magnetostrictive material 2 covered with the rigid layer 13, this ribbon undergoes deformations whose amplitudes are proportional to the variations in amplitude of the current. Due to the presence of the rigid layer, the ribbon undergoes deformations which are amplified in the same way as in a thermal bimetallic strip where it is temperature variations which cause such deformations. It follows that the speaker formed using such a ribbon has a very wide bandwidth in the range of audible frequencies, including for low frequencies or its power is much greater than for the speakers state of the art spherical.

FIG. 5 schematically represents a side view of another variant of a magnetostrictive tape used in the loudspeaker of the invention. The ribbon has wavy waves here along its entire length transverse tions. Each corrugation has on the face 12 of the ribbon, directed towards the interior I of the sphere, a concave zone 14A and a convex zone 14B. Each corrugation also has on the face 11 of the ribbon, directed towards the outside E of the sphere, a concave zone 15A and a convex zone 15B. In this variant, the rigid thin layer does not extend over the whole of one of the faces of the ribbon, but it is located at least partially opposite the convex zones 15B of the face 11 of the ribbon, directed towards the outside. E of the sphere. This rigid thin layer is shown at 16 in the figure.

The presence of undulations significantly increases the amplitudes of the deformations to which the magnetostrictive tape 2 is subjected, when an electric current of variable amplitude and frequency is applied to it. In fact, the edges such as 17, 18 of the convex zone 15B of the corrugation approach significantly, in proportion to the amplitude of the electric current applied, due to the presence of copper layer 16 which causes the effect bimetallic strip described above.

FIG. 6 schematically represents a side view of another variant of the magnetostrictive tape. In this variant, and in order to further increase the amplitude of the deformations of the ribbon, in particular at low frequencies, the magnetostrictive ribbon has transverse undulations over its entire length. Each corrugation has, as in the previous embodiment, on its face 12 directed towards the interior I of the sphere, a concave zone 14A, and a convex zone 14B and on its face 11, directed towards the exterior of the sphere , a concave zone 15A and a convex zone 15B. The rigid layer is here partially located opposite the zones concaves 14A and 15A on each side of the ribbon. These localized rigid thin layers are shown at 19, 20 in the figure. The passage of electric current through the ribbon here causes the edges of the corrugations to spread apart.

FIG. 7 schematically represents a side view of another variant of a magnetostrictive tape used in the loudspeaker of the invention. The rigid thin layer is here partially deposited on each of the faces of the ribbon, facing the convex zones 14B, 15B of the corrugations. These localized rigid thin layers are shown at 21, 22 in the figure. As in the previous embodiment, the amplitude of the deformations of the ribbon, in particular at low frequencies, is very large due to the bimetal effect of the structure of the ribbon described. The passage of electric current through the ribbon here brings the edges of the corrugations together.

To facilitate the realization and in particular when the source of continuous polarization is constituted by a permanent magnet, the membrane constituted by the ribbon 2, partially covered with rigid material, and by the elastic support 1, can be formed of two hemispheres, such as represented in 23 , 24, in FIG. 1. These two hemispheres are made integral, for example by gluing the support and by welding two half-ribbons, each corresponding to one of the hemispheres.

The preferred embodiments of the loudspeaker which has just been described are those which use the magnetostrictive ribbon with bimetal effect, of wavy shape. It is indeed this wavy shape which provides the best acoustic performance and which ensures the simplest manufacture of the spherical loudspeaker.

Claims (7)

1. Omnidirectional loudspeaker comprising a spherical membrane which comprises turns formed by a ribbon (2) of a magnetostrictive material wound in a spiral according to a sphere, these turns being held by an elastic support (1), so that they form with said support said spherical membrane, this ribbon having two opposite faces (11, 12) one of which is directed towards the inside (I) of the sphere and the other towards the outside (E), and two ends (3, 4) situated in two diametrically opposite zones of the sphere, to be connected to an electrical control means (5) supplying a signal corresponding to sound waves to be reproduced, and a means (7) for continuous polarization of the membrane, characterized in that at least one of the faces (11) of the ribbon (2) is at least partially covered with a thin layer (13) of a rigid material. 2. Loudspeaker according to claim 1, characterized in that the ribbon (2) is covered by the rigid thin layer (13) on its face (11) directed towards the outside (E) of the sphere. 3. Loudspeaker according to claim 1, characterized in that the strip (2) has over its entire length transverse undulations, each undulation having on the face (12) of the ribbon, directed towards the inside (I) of the sphere, a concave zone (14A) and a convex zone 14B, and on the face (11) of the ribbon directed towards the outside (E) of the sphere, a concave zone (15A) and a convex zone (15B), the rigid layer (16) being located at least partially on the face (11) of the ribbon, directed towards the outside (E) of the sphere, opposite the convex zones (15B) of this face. 4. Loudspeaker according to claim 1, characterized in that the ribbon (2) has over its entire length transverse corrugations, each corrugation having on the face (12) of the ribbon, directed towards the inside of the sphere, a concave zone (15A) and a convex zone (15B) and on the face (11) of the ribbon, directed towards the outside of the sphere, a concave zone (15A) and a convex zone (15B), the rigid layer (19 , 20 or 21, 22) being located partially on each side of the strip, facing the concave areas (14A, 15A) or facing the convex areas (14B, 15B). 5. Speaker according to any one of claims 1 to 4, characterized in that the means for continuous polarization of the membrane is a permanent magnet (10) located inside said membrane. 6. Speaker according to any one of claims 1 to 4, characterized in that the DC biasing means is a DC voltage source (7) connected to the ends of said ribbon. 7. Speaker according to any one of claims 1 to 4, characterized in that said membrane is formed of two hemispheres (23, 24) joined to one another.

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