EP1515584A1 - Loudspeaker and corresponding loudspeaker enclosure - Google Patents

Abstract

The loudspeaker has a sound production assembly positioned inside a cavity created by a membrane (313) of another sound production assembly. The former assembly has a coil (321) integrated with a membrane (323), a foam dome (328) for damping vibration of the membrane (323), and a magnetic circuit. The latter assembly has another magnetic circuit positioned inside the created cavity. An independent claim is also included for a speaker system comprising a loudspeaker.

Description

The present invention relates to the field of sound and audio and more specifically, the invention relates to loudspeakers and loudspeakers corresponding.

Traditionally, speakers produce sound through vibration of a membrane. An electric coil attached to the membrane and which moves in a gap where there is a magnetic field (the air gap being understood between a cylinder head and a core), sets the membrane in motion when the coil is covered by an electric current. The magnetic field comes from a stream magnet created by a magnet and circulating in the cylinder head, the core and the gap. The latter makes it possible to control in intensity and frequency the vibrations of the membrane and therefore the desired sound reproduction.

• un châssis (ou saladier) 14 ;
• un aimant 12 en ferrite;
• une culasse avec noyau 18 ; et
• une plaque de champ 19.

Figure 1 shows an electrodynamic loudspeaker 10 known per se. The loudspeaker 10 is axially symmetrical and comprises the following fixed parts:

• a frame (or salad bowl) 14;
• a magnet 12 made of ferrite;
• a breech with core 18; and
• a field plate 19.

• une suspension intérieure (ou « spider ») 16 dans sa partie centrale ; et
• une suspension périphérique 15.

The speaker 10 also comprises a membrane 13 which flares between a central portion of small radius and a peripheral portion of higher radius. In order to limit the movements of the membrane 13 and to ensure good mechanical strength, the latter is connected to the frame 14 by:

• an inner suspension (or "spider") 16 in its central part; and
• a peripheral suspension 15.

The central portion of the membrane 13 is closed by a core cover 17 located approximately at the same level as the suspension 15. An electric coil 11 is integral with the central portion of the membrane. This coil can move freely parallel to the axis of the speaker 10 in a gap between the field plate 19 and the core 18 which create a magnetic field B. Thus, the coil 11 moves along the axis of the speaker 10 in one direction or the other depending on the current I that runs through it. It then drives in its movement the membrane 13 which produces sound, the force F exerted on the membrane being equal to the product of the magnetic field B by the length L of the son of the coil 11 and the current I ( F = B. L. I ).

A disadvantage of this state of the art is that it does not make it possible to obtain compact speakers, the magnetic circuit (including in particular the coil, the magnet and the core) being placed at the rear of this assembly.

To reduce the volume occupied by a speaker, we place the circuit magnetic inside the chassis / membrane assembly to form a speaker said "reverse engine".

• une bobine 21 solidaire de la membrane 23 ;
• une culasse 28, une plaque de champ 29 et un aimant 22 en ferrite associés de manière rigide au châssis 24.

   l'ensemble bobine 21 et membrane 23 est associé de manière souple au châssis 24 par l'intermédiaire de suspensions centrale 26 et périphérique 25. FIG. 2 illustrates such a loudspeaker 20 which comprises a frame 24, a membrane 23 and a magnetic circuit including itself:

• a coil 21 integral with the membrane 23;
• a yoke 28, a field plate 29 and a ferrite magnet 22 rigidly associated with the frame 24.

the coil assembly 21 and membrane 23 is flexibly associated with the chassis 24 via central and peripheral suspensions 26.

Since the magnetic circuit is completely inserted inside the membrane 23, the depth P of the loudspeaker 20 is directly related to the difference in dimension along the axis of the loudspeaker 20 between the peripheral suspension 25 and the frame 24.

A disadvantage of this technique is that it does not make it possible to obtain loudspeaker speakers; we thus have bass speakers frequencies (up to 500 Hz) (or "boomer"), of medium frequencies (between 200 and 3000 Hz) (or "medium").

To benefit from a broad spectrum, it is then necessary to have two or three speakers (implemented, for example, in an acoustic enclosure). A another disadvantage is then the relatively large volume occupied by several loudspeakers, especially when they are used in restricted (small speakers, cars, narrow walls, ...).

Still, another disadvantage of this technique is that it is not usable for "tweeters" (high frequency speaker).

The invention in its various aspects is intended in particular to overcome these disadvantages of the prior art.

More specifically, an object of the invention is to provide a loudspeaker for wide sound spectrum.

The invention also aims to reduce the size of the loudspeaker while maintaining a wide sound spectrum.

A complementary object of the invention is to provide a loudspeaker to produce a good quality sound (including high fidelity) particularly well suited to a wide variety of environments (for example, for apartment acoustic speaker, for home theater systems, for systems intended for vehicles (in particular to be placed in dashboards or seats), for audio-video devices ...).

Yet another object of the invention is to provide a sound source for spatial coherence with limited and well-controlled diffraction effects. More precisely, an objective of the invention is to obtain a directivity index (noted DI) which grows regularly and without accident (or discontinuity) depending of the frequency.

An object of the invention is also to enable a production relatively easy of the speaker.

• une première membrane ; et
• des premiers moyens électromagnétiques pour actionner la première membrane ;

For this purpose, the invention proposes a loudspeaker comprising a cylinder head and first sound production means in a first frequency band including themselves:

• a first membrane; and
• first electromagnetic means for actuating the first membrane;

• une deuxième membrane ; et
• des deuxièmes moyens électromagnétiques pour actionner la deuxième membrane, les deuxièmes moyens électromagnétiques étant montés sensiblement sur l'axe.

the yoke and the first electromagnetic means being positioned substantially inside the cavity created by the first membrane and being mounted substantially on the same axis. The loudspeaker is remarkable in that it further comprises second sound generation means in a second frequency band including themselves:

• a second membrane; and
• second electromagnetic means for actuating the second membrane, the second electromagnetic means being mounted substantially on the axis.

According to one particular characteristic, the loudspeaker is remarkable in what the second membrane and the second electromagnetic means are positioned substantially within the cavity.

Thus, the size of the loudspeaker is reduced, the mounting of the loudspeaker remaining simple.

In addition, the quality of the sound produced is good and compatible with high fidelity sound reproduction.

Moreover, the spatial diffusion is optimized for the sound produced by the second membrane.

• un premier aimant ;
• une première plaque de champ ;
• une première bobine associée à la première membrane et située dans un entrefer compris entre la première plaque de champ et le noyau de la culasse de sorte à actionner la première membrane lorsque la première bobine est parcourue par un courant électrique.

According to one particular characteristic, the loudspeaker is remarkable in that the first electromagnetic means comprise

• a first magnet;
• a first field plate;
• a first coil associated with the first membrane and located in an air gap between the first field plate and the core of the cylinder head so as to actuate the first membrane when the first coil is traversed by an electric current.

• un deuxième aimant ;
• une deuxième plaque de champ ;
• une deuxième bobine associée à la première membrane et située dans un entrefer compris entre la deuxième plaque de champ et le noyau de la culasse de sorte à actionner la deuxième membrane lorsque la deuxième bobine est parcourue par un courant électrique.

According to one particular characteristic, the loudspeaker is remarkable in that second electromagnetic means for actuating the second membrane comprise:

• a second magnet;
• a second field plate;
• a second coil associated with the first membrane and located in a gap between the second field plate and the core of the cylinder head so as to actuate the second membrane when the second coil is traversed by an electric current.

According to one particular characteristic, the loudspeaker is remarkable in that that the cylinder head is contiguous to the first and second magnets by presenting a magnetization of the same polarization in the zones of the cylinder head contiguous to first and second electromagnetic means.

Thus, the cylinder head can be made in one part, which simplifies its manufacturing.

According to one particular characteristic, the loudspeaker is remarkable in that that the cylinder head is contiguous to the first and second magnets by presenting a opposite polarization magnetization in the zones of the cylinder head contiguous with the first and second electromagnetic means.

In this way, the magnetizations impose a flow circulation associated with the first and second means respectively electromagnetic and circulating in the cylinder head. Thus, flows (in absolute value) entrench themselves in the breech, which reduces the section and therefore the breech height. In this way, it is possible to reduce the bulk or the height of the speaker.

Moreover, the flow flowing in the cylinder head being lower, the losses Magnetics are also lower and the speaker output is better. A compromise can be found more easily to reduce the size loudspeaker according to the desired performance.

The cylinder head is then preferably produced in two parts.

According to one particular characteristic, the loudspeaker is remarkable in that that the first and second sound production means are configured from so that the first and second frequency bands cover a spectrum continuous by presenting an almost constant acoustic response between two predetermined extreme frequency values.

Thus, the speaker is well suited for use in a broadband frequency (eg covering the mid and high frequencies) of good quality of sound reproduction (high fidelity).

According to one particular characteristic, the loudspeaker is remarkable in that that the first means of sound production are configured so that the first frequency band corresponds to a medium band covering at least frequencies of the order of 500 to 3000 Hz.

The frequencies of the order 500 to 3000 Hz (or even lower) correspond at very useful frequencies in the audio field and in particular the human vocal restitution.

In addition, a membrane associated with a medium band covering frequencies of about 500 to 3000 Hz (or even lower) has a diameter relatively large to accommodate, inside the cavity formed by the membrane, the second means of sound production.

• une troisième membrane ;
• un troisième noyau ;
• des troisièmes moyens électromagnétiques pour actionner la troisième membrane ;
• les troisièmes moyens électromagnétiques étant montés sensiblement sur l'axe.

According to one particular characteristic, the loudspeaker is remarkable in that the loudspeaker further comprises at least third sound generation means in at least a third frequency band each comprising:

• a third membrane;
• a third nucleus;
• third electromagnetic means for actuating the third membrane;
• the third electromagnetic means being mounted substantially on the axis.

Thus, the loudspeaker can have a very large bandwidth which covers, for example, low, mid and high frequencies while having a reduced size and maintaining a great ease of assembly.

We note that the third core and the third magnet is preferentially common with respectively the first or second core and / or the first or second magnet to optimize the reduction of the size and / or height of the speaker.

According to one particular characteristic, the loudspeaker is remarkable in that at least one of the magnets is of the rare-earth type.

Thus, it is possible to optimize the efficiency (or output) of the speaker and / or reduce its bulk.

According to one particular characteristic, the loudspeaker is remarkable in that at least one of the magnets is of the Neodymium-Iron-Bore (NeFeB) type.

Thus, it is possible to reduce manufacturing costs, the Neodymium-Iron-Boron being a relatively common compound.

It is possible to use a magnet comprising Samarium-Cobalt so to obtain a better hold of the speaker at high temperatures (especially above 120 ° C).

According to one particular characteristic, the loudspeaker is remarkable in that that the first membrane is concave seen from the outside of the loudspeaker.

According to one particular characteristic, the loudspeaker is remarkable in that that the first membrane is convex from the outside of the loudspeaker.

Thus, the first membrane being convex minimizes the effects of diffraction because it leads to a continuity of the surface in the environment of the second means of sound production (for example " Tweeter ").

• une première membrane ; et
• des premiers moyens électromagnétiques pour actionner la première membrane ;

The invention also relates to an acoustic enclosure, comprising at least one loudspeaker as described above and comprising, in particular, a cylinder head and first sound production means in a first frequency band including themselves:

• a first membrane; and
• first electromagnetic means for actuating the first membrane;

• une deuxième membrane ; et
• des deuxièmes moyens électromagnétiques pour actionner la deuxième membrane, les deuxièmes moyens électromagnétiques étant montés sensiblement sur l'axe.

the yoke and the first electromagnetic means being positioned substantially inside the cavity created by the first membrane and being mounted substantially on the same axis, the speaker being remarkable in that it further comprises second means sound production in a second frequency band including themselves:

• a second membrane; and
• second electromagnetic means for actuating the second membrane, the second electromagnetic means being mounted substantially on the axis.

Thus, to cover a given bandwidth, the number of loudspeakers in an acoustic enclosure is reduced. The assembly of the speaker is therefore simplified.

The advantages of the speaker are the same as those of the speaker, they are not detailed further.

• les figures 1 et 2 présentent des haut-parleurs connus en soi ;
• la figure 3 présente une coupe d'un haut-parleur à deux membranes conforme à l'invention selon un mode particulier de réalisation ;
• les figures 4 à 8 illustrent des variantes du haut-parleur illustré en regard de la figure 3 ;
• les figures 10 et 11 illustrent un haut-parleur à trois membranes et à deux aimants (un aimant étant commun aux graves et aux médiums), conforme à l'invention selon des modes particuliers de réalisation ; et
• les figures 12 et 13 présentent des variantes de circuits magnétiques mis en oeuvre dans le haut-parleur illustré en figure 3.

Other features and advantages of the invention will appear more clearly on reading the following description of a preferred embodiment, given as a simple illustrative and non-limiting example, and the appended drawings, among which:

• Figures 1 and 2 show loudspeakers known per se;
• Figure 3 shows a section of a speaker with two membranes according to the invention according to a particular embodiment;
• Figures 4 to 8 illustrate variants of the speaker illustrated with reference to Figure 3;
• Figures 10 and 11 illustrate a speaker with three membranes and two magnets (a magnet being common to the bass and midrange), according to the invention according to particular embodiments; and
• FIGS. 12 and 13 show variants of magnetic circuits implemented in the loudspeaker illustrated in FIG.

The general principle of the invention is based on an original installation of the loudspeaker reverse motor which comprises at least two associated membranes each to a spectrum of sound frequencies coaxially mounted. So, the loudspeaker depth is essentially a function of the clutter of the chassis and outer membrane (producing the lowest frequencies sound).

In addition, the loudspeaker efficiency (i.e. performance associated with acoustic level for power consumption given), while maintaining a very small magnetic circuit volume, in using rare-earth type magnets (for example of the Neodymium-Iron-Boron type (or NdFeB) or Samarium-Cobalt (SmCo)). Indeed, the magnetic energy is about ten times stronger in rare-earth magnets than in ferritic magnets. Thus, it is possible to reduce the volume of magnets by about one factor ten or increase the efficiency of magnets by reducing the volume of magnets by a factor of less than ten.

With reference to FIG. 3 , an embodiment of a two-diaphragm loudspeaker 30 according to the invention is presented.

• un châssis 34 ;
• une culasse cylindrique 38 placé sur l'axe du haut-parleur 30;
• un premier ensemble de production sonore dans les fréquences médiums (par exemple 500 Hz à 5 kHz) ; et
• un second ensemble de production sonore dans les fréquences aiguës. Le premier ensemble de production sonore comprend :

• une membrane 313 d'un diamètre externe d'environ 8 cm (ce diamètre pouvant être beaucoup plus grand selon des variantes de réalisation de l'invention), associée de manière souple au châssis 34 par l'intermédiaire de suspensions centrale 36 et périphérique 315 ;
• une bobine 311 solidaire de la membrane 313 ; et
• un premier circuit magnétique situé sensiblement à l'intérieur de la cavité créée par la membrane 313 et qui comprend lui même :

• une plaque de champ 316 et un aimant 312 en terres rares (par exemple de type Néodyme-Fer-Bore (ou NdFeB)) associés de manière rigide au châssis 34 ; et
• la culasse 38 destinée, avec la plaque de champ 316, à fermer le flux magnétique créé l'aimant 312.

The loudspeaker 30 is substantially axially symmetrical and comprises the following elements mounted on the same axis 33:

• a frame 34;
• a cylindrical yoke 38 placed on the axis of the speaker 30;
• a first set of sound production in the mid frequencies (for example 500 Hz to 5 kHz); and
• a second set of sound production in the high frequencies. The first set of sound production includes:

• a membrane 313 with an external diameter of approximately 8 cm (this diameter being able to be much larger according to alternative embodiments of the invention), flexibly associated with the chassis 34 via central and peripheral suspensions 36 and 315 ;
• a coil 311 integral with the membrane 313; and
• a first magnetic circuit located substantially inside the cavity created by the membrane 313 and which comprises itself:

• a field plate 316 and a rare earth magnet 312 (for example of the Neodymium-Iron-Boron (or NdFeB) type) rigidly associated with the frame 34; and
• the yoke 38 intended, with the field plate 316, to close the magnetic flux created the magnet 312.

The magnet 312 is here outside the yoke 38, a space between the magnet 312 and the yoke 38 creating a magnetic field B1 in a first air gap in which the coil 311 can move in the direction of the axis 33.

• une membrane 323 d'un diamètre externe d'environ 3 cm, associée de manière souple à un support périphérique 327 (relié lui-même de manière rigide à la culasse 38 par l'intermédiaire d'une suspension périphérique 325) ;
• un dôme en mousse 328 destiné à amortir les vibrations de la membrane 323 et donc à régulariser la courbe de réponse du haut parleur 30 dans les aigus ;
• une bobine 321 solidaire de la membrane 323 ; et
• un second circuit magnétique qui comprend lui même un noyau 329 et un aimant 322 en terres rares (par exemple de type Néodyme-Fer-Bore ou NdFeB) associés de manière rigide à la culasse 38.

The second sound production assembly is located substantially inside the cavity created by the membrane 313 and comprises:

• a membrane 323 with an outside diameter of about 3 cm, flexibly associated with a peripheral support 327 (itself rigidly connected to the yoke 38 via a peripheral suspension 325);
• a foam dome 328 for damping the vibrations of the membrane 323 and thus regulating the response curve of the speaker 30 in the treble;
• a coil 321 secured to the membrane 323; and
• a second magnetic circuit which itself comprises a core 329 and a rare earth magnet 322 (for example of the Neodymium-Iron-Boron or NdFeB type) rigidly associated with the yoke 38.

According to a variant, in order to obtain a better thermal resistance the magnets 312 and 322 are made of rare earths of Samarium-Cobalt type.

The magnet 322 is here inside the yoke 38, a space located between the core 329 and the yoke 38 creating a magnetic field B2 in a second gap in which the coil 321 can move in the direction of the axis 33.

The coils 311 and 321 are respectively traversed by currents I1 and I2 independent. They cause in their movement respectively the membranes 313 and 323 which produce sound, the forces F1 and F2 exerted respectively on each membrane being equal to the product of the magnetic fields B1 and B2 by the length L1 and L2 of the son of the coils 311 and 321 and current I1 and I2 ( F1 = B1.L1.I1 and F2 = B2.L2.I2 ).

The speaker 30 makes it possible to produce sound in two ranges of frequencies, the sources at medium and high frequencies respectively being associated respectively with the first and the second magnetic circuits (for intermediate respectively currents I1 and I2).

The frequency response of the sound production sets is determined by shapes and dimensions according to rules known to man of career. Preferably (for example, for implementation in a loudspeaker), the currents supplying the coils 311 and 321 are also filtered so that the acoustic response of the speaker 30 is as constant as possible in the band under consideration (eg 500 Hz to 20 KHz) so that the sound output is of good quality.

In addition, the sound produced by each of the two membranes 313 and 323 is wide spatial diffusion and thus covers the same spatial area (for example in a room of house or in a vehicle) with average (membrane 313) and with high (membrane 323) frequency.

In addition, there is no abrupt break in the propagation paths of the its especially in the high frequencies, the diffraction of the acute sounds produced by the membrane 323 is therefore limited and well controlled.

The loudspeaker 30 thus makes it possible to produce sound with an answer quasi-linear or almost constant acoustic level in a wide spectrum while having a small footprint (the depth of the speaker is at illustrative title of 4.5 cm).

According to variants, the person skilled in the art can adapt the diameter of the membranes 313 and 323 (which may be less than or greater than 8 cm respectively) and at 3 cm), their depth and their shape (particularly conical profile, spherical, ...) depending on the sound characteristics (spectrum, directivity, ...) sought.

According to other variants, the magnets 312 and / or 322 are made of ferrite. The volume occupied by the corresponding magnetic circuits is then more large and is, for example, well suited for living room acoustic speakers.

According to other variants, the second set of sound production is not located substantially inside the cavity created by the membrane 313, while remaining coaxial with the first set of sound production: it can notably placed in a central recessed portion of the membrane 313 or outside of the cavity formed by the latter.

Figures 4 and 5 schematically show variants 40 and 50 of the speaker shown in Figure 3. The speakers 40 and 50 are especially well suited to domestic applications.

• un châssis 44 (respectivement 54) ;
• un culasse cylindrique 48 (respectivement 58) placée sur l'axe du haut-parleur 40 (respectivement 50); et
• des premier et second ensembles de production comprenant des membranes 413 et 423 (respectivement 513 et 523), des aimants 412 et 422 (respectivement 512 et 522), des plaques de champ 416 et 429 (respectivement 516 et 529), et des bobines 411 et 421 (respectivement 511 et 521).

The loudspeaker 40 (respectively 50) is substantially axially symmetrical and comprises the following elements mounted on the same axis respectively 43 (respectively 53):

• a frame 44 (respectively 54);
• a cylindrical yoke 48 (58 respectively) placed on the axis of the loudspeaker 40 (respectively 50); and
• first and second production assemblies comprising membranes 413 and 423 (respectively 513 and 523), magnets 412 and 422 (respectively 512 and 522), field plates 416 and 429 (respectively 516 and 529), and coils 411 and 421 (respectively 511 and 521).

These elements are similar to the corresponding elements of the speaker 30 previously illustrated. They will not be described further.

It is noted, however, that the diameter of the membranes is different (of the order of 11 cm for the membranes 413 and 513 and 2 cm for the membranes 423 and 523). The depth of the loudspeakers 40 and 50 is respectively of the order of 2.5 cm and 3 cm.

As for the loudspeaker 30, the medium membrane 513 is located at the inside of the frame 54: the membrane 513 is concave seen from the outside of the loudspeaker 50. The treble membrane 523 is convex. The first production assembly is not included between the frame 54 and the membrane 513. On the speaker 30, the volumes of the magnets are larger than on the loudspeaker 50. The efficiency of the loudspeaker 30 is therefore higher than that of the speaker 30. On the other hand, on the 30 speaker, the tweeter is more before on the speaker 50 and the total depth of the speaker 30 is greater than that of the loudspeaker 50.

On the other hand, for the loudspeaker 40, the membranes 413 and 423 are convex views from the outside of the speaker 40. Thus, the diffraction effects seen from the tweeter corresponding to the second set of production are minimized. The first production unit is in this case between frame 44 and the membrane 413.

Figures 6 to 8 schematically show variants 60, 70 and 80 of shown in Figure 3. The speakers 60, 70 and 80 are especially well suited to applications requiring small footprint as much in width as in depth (especially domestic applications or for vehicle acoustic systems).

• un châssis 64 (respectivement 74 et 84) ;
• un noyau cylindrique 68 (respectivement 78 et 88) placé sur l'axe du haut-parleur 60 (respectivement 70 et 80); et
• des premier et second ensembles de production comprenant des membranes 613 (respectivement 713 et 813) et 623 (respectivement 723 et 823), des aimants 612 (respectivement 712 et 812) et 622 (respectivement 722 et 822) et des bobines 611 (respectivement 711 et 811) et 621 (respectivement 721 et 821).

The loudspeaker 60 (respectively 70 and 80) is substantially axially symmetrical and comprises the following elements mounted on the same axis 63 (respectively 73 and 83):

• a frame 64 (respectively 74 and 84);
• a cylindrical core 68 (respectively 78 and 88) placed on the axis of the loudspeaker 60 (respectively 70 and 80); and
• first and second production assemblies comprising membranes 613 (respectively 713 and 813) and 623 (respectively 723 and 823), magnets 612 (respectively 712 and 812) and 622 (respectively 722 and 822) and coils 611 (respectively 711 and 811) and 621 (respectively 721 and 821).

These elements are similar to the corresponding elements of the speaker 30 previously illustrated. They will not be described further.

However, it is noted that the diameter of the membranes is lower (from the order of 6.5 cm and 5.5 cm respectively for membranes 713 and 813 and 1.5 cm for membranes 623, 723 and 823). The radius of curvature of speaker membranes 60, 70 and 80 is also lower than that of corresponding speakers of the speaker 30. The depth of the loudspeakers 60, 70 and 80 is of the order 3 cm.

• un faible diamètre ;
• une forte flèche ; et
• une grande rigidité du matériau.

To increase in frequency, in general, the membranes must have:

• a small diameter;
• a strong arrow; and
• a high rigidity of the material.

Figure 9 illustrates a speaker 90 (in view from above and in a section AA) comprising three membranes 913, 923 and 933 according to a particular embodiment of the invention.

• un châssis 94;
• une culasse cylindrique 98 placée sur l'axe 93 du haut-parleur 90 ;
• un premier ensemble de production sonore dans les fréquences graves (par exemple 100 Hz à 500 Hz), comprenant la membrane 913, un aimant 912, une plaque de champ 914 et une bobine 911 ;
• un deuxième ensemble de production sonore dans les fréquences médiums (par exemple 500 Hz à 5 KHz), comprenant la membrane 923, l'aimant 912, la plaque de champ 914 et une bobine 921 ; et
• un troisième ensemble de production sonore dans les fréquences aiguës (par exemple 5 KHz à 20 KHz), comprenant la membrane 933, un aimant 932, un noyau 934 et une bobine 931.

The loudspeaker 90 is substantially axially symmetrical and comprises the following elements mounted on the same axis 93:

• a chassis 94;
• a cylindrical yoke 98 placed on the axis 93 of the loudspeaker 90;
• a first set of sound production in the low frequencies (for example 100 Hz to 500 Hz), comprising the membrane 913, a magnet 912, a field plate 914 and a coil 911;
• a second set of sound production in the mid frequencies (for example 500 Hz to 5 KHz), comprising the membrane 923, the magnet 912, the field plate 914 and a coil 921; and
• a third set of sound production in the high frequencies (for example 5 KHz to 20 KHz), comprising the membrane 933, a magnet 932, a core 934 and a coil 931.

The cylinder head 98, the magnet 912 and the field plate 914 are common to first and second sets of sound production. However, they present two separate gaps to accommodate respectively the 911 coils and 921.

In addition, the second and third sets are positioned at inside a cavity formed by the concave membrane 913.

The frequency response of the sound production sets is determined by shapes and dimensions according to rules known to man of career. Preferably (for example, for implementation in a loudspeaker loudspeaker), the currents supplying the coils 911, 921 and 931 are further filtered by bandpass filters (possibly low-pass for bass and high-pass for treble) so that the acoustic response loudspeaker 90 is as constant as possible in the band example 100 Hz to 20 KHz) so that the sound output is good quality.

These elements are, moreover, similar to the corresponding elements of the speaker 30 illustrated previously. They will not be described further.

FIG. 10 illustrates a loudspeaker 100 (viewed from above and in a section BB) comprising three membranes 1013, 1023 and 1033 according to one particular embodiment of the invention.

The speaker 100 is similar to the speaker 90 illustrated above except for the grave membrane 1013 which is convex from the outside of the loudspeaker 100. Chassis 914, membranes 1013, 1023 and 1033, magnets 1012 and 1032, a cylinder head 108, a field plate 1014 and a core 1034 as well that coils 1011, 1021 and 1031 forming part of the loudspeaker 100 correspond respectively to frame 914, membranes 913, 923 and 933, to the magnets 912 and 932, to the cylinder head 98, to the field plate 914 and to the core 934, and the coils 911, 921 and 931 of the loudspeaker 90 and therefore will not be described further.

However, it is noted that, due to the convexity of the membrane 1013, the first set of production (low frequencies associated with the membrane 1013) of the loudspeaker 90 is, in this case, between the frame 1004 and the 1013 membrane unlike the corresponding element of the speaker 90 (which is located inside the concavity of the 913 membrane and therefore outside of the area between the membrane 913 and the frame 94). Thus, the effects of diffraction on medium and high production sets (membranes 1023 and 1033) are miniminated.

Figure 11 shows in more detail the magnetic circuits of the speaker 30 illustrated with reference to Figure 3 and in particular the magnetic flux.

The first magnetic circuit creates a circulating magnetic flux 319 successively in the magnet 312, the field plate 316, a gap and the cylinder 38, the magnet 312 being polarized negatively (zone 317) and positively (zone 318) in contact respectively with the field plate 316 and the cylinder head 38.

Similarly, the second magnetic circuit creates a magnetic flux 3212 circulating successively in the magnet 322, the core 329, an air gap and the cylinder head 38, the magnet 312 being positively polarized (zone 3211) and negatively (zone 3210) in contact with the core 329 and the yoke 38, respectively.

The polarizations of the magnets 312 and 322 impose the direction of circulation flows 319 and 3212 which is the same in the common area of the bolt 38. The flows 319 and 3212 are therefore added to the common traffic zone. By elsewhere, losses that depend on the materials used and the reluctance of the magnetic circuit components requires a sufficient breech section to avoid saturation.

In order to reduce the height h1 of the magnetic circuits and / or to limit the magnetic losses in the cylinder head, according to the variant illustrated with reference to FIG. 12 , first and second magnetic circuits are used whose cylinder head comprises two parts 121 and 122 respectively contiguous to magnets 123 (similar to the magnet 322 but inverted polarization) and 312. This implementation allows a polarization such that the magnetic flux is hiding (in absolute value) instead of adding.

The elements common to the magnetic circuits of FIGS. 11 and 12 (magnet 312, core 316, ...) have the same references and will not be described more.

Thus, the polarization of the magnet 312 (zones 318 and 317) remains unchanged, the first magnetic flux 319 therefore flows in the same direction.

On the other hand, the magnet 123 is negatively polarized (zone 1221) and negatively (zone 1220) in contact with core 329 and the 122 of the cylinder head 38, which imposes a direction of circulation of a magnetic flux 1222 opposite to the flow direction of the flow 3212 illustrated in FIG. 11.

Thus, the flows 1222 and 319 circulate in the opposite direction in the cylinder head 38 which makes it possible to reduce its height h2 and / or the magnetic losses in the cylinder head.

• soit d'un seul tenant imposant des circulations de flux identiques ;
• soit en deux parties avec une polarisation des aimants correspondant permettant une circulation des flux en sens opposé afin de réduire la hauteur de culasse et/ou les pertes magnétiques dans la culasse.

The same variants are of course possible for the various loudspeakers embodying the invention. Thus, the yokes 48, 58, 68, 78, 88, 98 and 108 of the corresponding loudspeakers may be:

• either in one piece imposing identical flow flows;
• or in two parts with a polarization of the corresponding magnets allowing flow flows in opposite directions to reduce the head height and / or magnetic losses in the cylinder head.

Of course, the invention is not limited to the embodiments mentioned above.

In particular, the skilled person can bring any variant into the form and material of the various constituents of the loudspeaker (in particular frame, membrane, coil, magnet, suspensions, yoke and core).

The skilled person may also make any variant in the sound spectrum of the loudspeakers according to the invention (for example band of frequencies from 200 Hz to 20000 Hz or 50 to 1000 Hz or 50 to 20000 Hz).

• domaine domestique, par exemple, haut-parleurs destinés aux enceintes de salon ou à des systèmes de type home-cinéma ;
• domaine des véhicules (par exemple automobiles, camions, avions, trains, bateaux, ...) notamment haut-parleurs insérés dans des sièges ou des tableaux de bord ou plus généralement dans un habitacle du conducteur et/ou des passagers ;
• domaine des équipements audio, vidéo et/ou multimédia, par exemple chaínes haute fidélité, appareil de production musicale, téléviseurs, ordinateurs, consoles de jeu ou informatiques, appareils de télécommunication (téléphones notamment),... ;
• et plus généralement domaine du son et/ou de l'image, par exemple équipements de studio, casques audio, équipements de salle de concert ou de conférence.

According to the invention, the loudspeakers have many applications in a wide variety of fields, including:

• home range, for example, speakers for living room speakers or home theater systems;
• field of vehicles (eg automobiles, trucks, airplanes, trains, boats, ...) including speakers inserted in seats or dashboards or more generally in a passenger compartment of the driver and / or passengers;
• field of audio, video and / or multimedia equipment, for example high-fidelity channels, musical production apparatus, televisions, computers, game consoles or computer systems, telecommunication apparatus (in particular telephones), ...;
• and more generally the field of sound and / or image, for example studio equipment, headphones, concert hall or conference equipment.

The invention also relates to equipment implementing loudspeakers according to the invention, in particular loudspeakers, headphones audio, vehicle seats or dashboards, audio equipment, video and / or multimedia comprising such loudspeakers.

Claims (12)

A loudspeaker (40) comprising a yoke (48) and first sound generating means in a first frequency band including themselves: a first membrane (413, 1013); and first electromagnetic means (411, 412, 416) for actuating said first membrane; said yoke and said first electromagnetic means being positioned substantially inside the cavity created by said first membrane and being mounted substantially on the same axis (43),
characterized in that said first membrane (413, 1013) is convex from the outside of said speaker
and in that said loudspeaker further comprises second sound generating means in a second frequency band including themselves: a second membrane (423); and second electromagnetic means (421, 422, 426, 429) for
actuating said second membrane; said second electromagnetic means being mounted substantially on said axis. Loudspeaker according to claim 1, characterized in that said second membrane and said second electromagnetic means are positioned substantially within said cavity. Loudspeaker according to any one of claims 1 and 2, characterized in that said first electromagnetic means comprise a first magnet (412); a first field plate (416); a first coil (411) associated with said first membrane and located in an air gap between said first field plate and the core of said cylinder head so as to actuate said first membrane when said first coil is traversed by an electric current. Loudspeaker according to any one of claims 1 to 3, characterized in that second electromagnetic means for actuating said second membrane comprise: a second magnet (422); a second field plate; a second coil (421) associated with said first membrane and located in a gap between said second field plate and the core of said cylinder head so as to actuate said second membrane when said second coil is traversed by an electric current. Loudspeaker according to any one of claims 1 to 4, characterized in that said yoke (48) is contiguous to said first and second magnets (412, 422) having a magnetization of the same polarization (319, 3212) in the zones said cylinder head contiguous to said first and second electromagnetic means. Loudspeaker according to any one of claims 1 to 4, characterized in that said yoke is contiguous to said first and second magnets (412, 423) having opposite polarization magnetization (319, 1222) in the areas of said cylinder head contiguous to said first and second electromagnetic means. A loudspeaker according to any one of claims 1 to 6, characterized in that said first and second sound generating means are configured so that said first and second frequency bands cover a continuous spectrum with an almost constant acoustic response between two predetermined extreme frequency values. Loudspeaker according to any one of claims 1 to 7, characterized in that said first sound production means are configured so that said first frequency band corresponds to a medium band covering at least frequencies of the order from 500 to 3000 Hz. A loudspeaker according to any of claims 1 to 8, characterized in that said loudspeaker further comprises at least third sound generating means in at least a third frequency band each comprising: a third membrane (1033); a third nucleus (1034); third electromagnetic means (1032, 1031) for actuating said third membrane; said third electromagnetic means being mounted substantially on said axis. Loudspeaker according to one of Claims 1 to 9, characterized in that at least one of said magnets is of the rare-earth type. Loudspeaker according to claim 10, characterized in that at least one of said magnets is of the Neodyme-Fer-Bore type. Acoustic speaker, characterized in that it comprises at least one loudspeaker (40) according to any one of claims 1 to 11.

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