IT202100032897A1 - TRANSDUCER FOR A SOUND SPEAKER AND METHOD FOR PRODUCING THE TRANSDUCER. - Google Patents

Description

DESCRIPTION

Attached to patent application for INDUSTRIAL INVENTION having as title

?TRANSDUCER FOR A SPEAKER AND METHOD FOR

TRANSDUCER PRODUCTION?

The present invention relates to a transducer for an acoustic speaker, an acoustic speaker and a method for producing the transducer.

The field of the present invention? that of acoustic reproduction systems, and in particular of acoustic speakers in which? more and more felt the need? to have a product capable of providing good acoustic performance and, at the same time, capable of maintaining small dimensions. In other words, ? more and more felt the need? to obtain compact speakers but, at the same time, capable of guaranteeing high acoustic performance in terms of the value of the SPL (Sound Pressure Level) parameter. As ? known, loudspeakers require the presence of an electromechanical transducer in which a coil or magnets are mobile.

An example of such transducers? shown in EP0508570A2 where a magnet is mobile in translation within a space delimited by a core of low reluctance magnetic material on which it is wound a coil. In this situation, the coil is powered by an excitation current so that the magnets are immersed in a magnetic field and move in translation along the vertical direction. These magnets, being associated with the membrane of the acoustic diffuser, cause its movement and therefore a variation in the acoustic load volumes suitable for producing the sound coming out of the acoustic diffuser.

Disadvantageously, the transducer shown in EP0508570A2 has numerous drawbacks related to size and performance.

In more detail, in case there is a need? to increase the power required to operate the speaker, the mass of the magnets increases. In this situation, their movement is particularly complex and costly in terms of energy expenditure. Furthermore, in case there is a need? to increase the power required for the operation of the loudspeaker, the latter sees its dimensions, and consequently its weight and cost, increase considerably. A further inconvenience? given by the arrangement of the magnets with respect to the coil. In fact, during the movement of the magnets, they are not kept totally immersed in the generated magnetic field. In this situation, the portions not immersed in the magnetic field cause losses which affect the overall efficiency of the acoustic transducer.

The technical task of the present invention is therefore to provide a transducer for an acoustic speaker, an acoustic speaker and a method for producing the transducer which are capable of overcoming the drawbacks that have emerged from the prior art.

The aim of the present invention is therefore to provide a translator which allows to generate high mechanical movements of the acoustic membrane of the speaker associated with it without increasing its overall dimensions, especially the dimensions in the direction of movement of the magnets.

A further aim of the present invention is therefore to provide a transducer which is capable of generating high forces and movement with low energy expenditure.

A further aim of the present invention is therefore to provide a method for producing the transducer which is simple and efficient.

The specified technical task and the specified objects are substantially achieved by a transducer for an acoustic speaker, an acoustic speaker and a method for producing the transducer comprising the technical characteristics set out in one or more? of the joint claims. The dependent claims correspond to possible embodiments of the invention.

In particular, the specified technical task and the specified purposes are achieved by a transducer for an acoustic speaker.

Preferably, but not limitedly, the transducer is used in the context of loudspeakers for sound reproduction.

The transducer object of the present invention could also find use in so-called bass boards.

Alternatively, the transducer ? suitable for use in active noise and vibration control systems for helicopters and similar vehicles. Alternatively, the transducer is used in active vibration dampers for vehicles, for example trucks and the like, and/or within car suspensions.

? else? It is expected that the transducer can be used for destructive vibration testing and/or in materials testing equipment (e.g. tensile/compression testing machines).

The transducer could also find use in vibrating conveyors. The transducer could also find use in energy harvesting systems.

The transducer comprises a coil including a plurality of of turns each lying on a respective lying plane transverse to a longitudinal axis. The spirals are juxtaposed along the longitudinal axis. The transducer further comprises a ferromagnetic circuit including a core, provided with a central portion around which the coil is positioned. wrapped, and an external lateral portion located laterally to the reel and at least partially surrounding the reel itself.

The external lateral portion? separated from the core by an air gap, i.e. by air. The air gap? extended longitudinally.

The transducer further includes at least one magnet located within the air gap. The magnet? a permanent magnet, i.e. a magnetized body capable of creating its own magnetic field.

According to one aspect of the invention, the magnet has a first end? and a second end?. In this situation, the magnet has a south pole and a north pole extending between the first end and the second end? parallel to the longitudinal axis.

In other words, the magnet has two opposing faces with opposite polarization.

The magnet? mobile, within the air gap, along a movement direction parallel to the longitudinal axis.

In more detail, the movement of the magnet along the movement direction? induced by an excitation magnetic field generated by an excitation of the coil, i.e. by the passage of an electric current within the coil.

? else? provided that the ferromagnetic circuit includes an internal lateral portion located laterally to the coil and placed between the coil and the at least one magnet.

The internal lateral portion has a high permeability area. magnetic in proximity? of (or facing the) coil.

In a possible embodiment, the high permeability area? magnetic? defined by a notch transverse to the longitudinal axis such as to divide the internal lateral portion into an upper sub-portion and a lower sub-portion juxtaposed along a direction parallel to the longitudinal axis and defining respective pole expansions facing the air gap. In a possible embodiment, the upper sub-portion and the lower sub-portion of the internal lateral portion (and therefore the internal lateral portion) are made integral with the core and project from the central portion towards the external lateral portion, wrapping the coil.

In other words, the upper sub-portion and the lower sub-portion develop in such a way as to almost entirely wrap the coil, leaving only the area close to the notch free so that the coil can face, in this area, towards the air gap and the magnet.

In accordance with a possible architecture of the transducer, and in particular in accordance with a radial architecture, the coil has a substantially circular shape. In this situation, the external lateral portion has an annular shape defining an external ring surrounding the coil. The outer ring? concentric to the coil and forms a circular crown with the latter defining the air gap ?T?.

In this embodiment, the magnet also has an annular shape and defines a magnetic ring entirely surrounding the coil. The magnetic ring? positioned within the air gap ?T? in such a way that one of the north and south poles faces entirely towards the coil for the entire circular development of the coil itself, while the other pole faces towards the external side wall.

Like the external side wall, the internal side wall also has an annular shape and defines an internal ring surrounding the coil. The inner ring? placed between the coil and the magnetic ring. In this situation, the coil is entirely embedded within the ferromagnetic circuit and faces towards the air gap only for the part left free by the notch. The radial architecture of the transducer is particularly advantageous as it allows the efficiency of the transducer to be increased while maintaining compact dimensions.

In accordance with a further possible architecture of the transducer, the coil has an elongated shape along a prevailing direction of development transverse to the longitudinal axis.

In this embodiment, the coil includes a first rectilinear portion parallel to the prevailing direction of development and a second rectilinear portion facing the first rectilinear portion and parallel to the prevailing direction of development.

The first and second straight portions are joined together by respective rounded connecting portions transverse to the prevailing direction of development.

In this embodiment, the external lateral portion includes a first and a second part supported by each other and positioned laterally to the reel symmetrically with respect to the longitudinal axis.

The first and second parts of the external lateral portion have a substantially parallelepiped shape and develop parallel to the prevailing direction of development.

The first and second parts of the external lateral portion respectively face the first straight portion and the second straight portion of the reel. The first and second parts of the outer lateral portion are spaced from the first straight portion and the second straight portion of the coil by the air gap.

In the preferred embodiment, the first and second parts of the external lateral portion present, along the prevailing direction of development, substantially the same extension as the first straight portion and the second straight portion of the coil.

In this embodiment, the transducer also includes a further magnet placed within the air gap symmetrically to the magnet with respect to the longitudinal axis. The additional magnet is a permanent magnet.

One between the magnet and the additional magnet? interposed between the first straight portion of the coil and the first part of the external lateral portion while the other is interposed between the second straight portion of the coil and the second part of the external lateral portion.

The additional magnet is mobile along a movement direction parallel to the longitudinal axis.

According to one aspect of this embodiment, the magnet and the further magnet respectively face the first and second rectilinear portions and have an elongated shape developing along respective axial directions parallel to the prevailing direction of development.

According to a further aspect, the first rectilinear portion and the magnet have the same axial extension thus? as the second straight portion and the further magnet have the same axial extension.

In use, when the coil is excited by the current to generate the excitation magnetic field, both the magnet and the additional magnet are moved, within the air gap, along the respective directions of movement. In particular, the magnetic field generated by the magnet and by the further magnet is perturbed by the excitation magnetic field so that the magnet and the further magnet translate (in lifting and lowering) along the respective directions of movement. This motion of the magnet and of the further magnet causes an oscillation of the speaker radiator to which the transducer? operationally connected.

So that? the magnet and the further magnet move simultaneously along the respective directions of movement, the transducer includes a support body operatively connected to the magnet and to the further magnet to make the movement of the magnet and the further magnet integral along the respective directions of movement when the coil? excited.

In accordance with one aspect of the description, the support body has a closed and elongated shape along the prevailing direction of development in such a way as to define, symmetrically with respect to the longitudinal axis, housing seats for the magnet and the further magnet.

In accordance with an aspect of the invention, the transducer further comprises a retaining band, preferably metallic, configured to prevent movement of the support body transversely to the longitudinal axis.

In other words, the retention band? configured to constrain the support body to translate along a direction parallel to the longitudinal axis following a movement of at least one magnet.

In accordance with one aspect of the description, the retention band ? elastically deformable so that a movement of the support body corresponds to a flexion of the retention band.

Advantageously, the retention band allows the movement of the magnets along the respective movement directions and, at the same time, avoids unwanted movement along different directions.

Advantageously, the retention band also guarantees compactness and tightness of the entire transducer.

The technical task and the intended objectives are also achieved by a method for the production of a transducer for an acoustic speaker.

The method includes a step of preparing a transducer comprising a coil equipped with a plurality of of turns each developing on a respective lying plane transverse to a longitudinal axis. The spirals are juxtaposed along the longitudinal axis. The transducer further comprises a ferromagnetic circuit comprising a core provided with a central portion around which the coil is wound and an external lateral portion located laterally to the coil and separated from the coil by an air gap. The transducer further comprises at least one magnetizable element.

In one possible embodiment, the transducer comprises a pair of magnetizable elements opposite and symmetrical with respect to the longitudinal axis.

The method also includes a step of positioning the at least one magnetizable element within the air gap and a step of setting up, externally the transducer, an auxiliary magnetization circuit configured to magnetize the magnetizable element.

The method then includes a magnetization phase of the at least one magnetizable element through an activation of the auxiliary magnetization circuit in such a way as to create a permanent magnet (or if there is a further magnetizable element, a further permanent magnet).

Advantageously, the possibility? to magnetize the magnetizable element once inside the transducer, allows to facilitate the assembly of the transducer itself.

Furthermore, the subject of the description is an acoustic diffuser comprising a housing body.

In one possible embodiment, the speaker can? also include a chest.

The acoustic speaker further comprises a transducer placed within the housing body and comprising a coil and at least one magnet, in particular a permanent magnet, movable with alternating motion along a direction of movement under the action of a magnetic field generated by the coil.

The acoustic diffuser further comprises a radiating structure including a suspension connected to the housing body and a radiator connected to the suspension.

The suspension ? configured to allow the radiator to swing relative to the housing body.

In particular, the suspension allows the radiator to move with reciprocating motion along a longitudinal axis parallel to the direction of movement of the at least one magnet.

In this situation, the radiator is operationally coupled to at least one magnet so that a movement of the magnet along the direction of movement parallel to the longitudinal axis corresponds to an oscillation, and in particular an oscillation in the opposite direction, of the radiator along the longitudinal axis itself.

Advantageously, given that the mass belonging to the transducer is comparable with the mass of the acoustic coupling systems of the acoustic speaker, ? it is convenient to invert the motion of at least one magnet with respect to that of the radiator to allow the masses in play to be inertially opposed in such a way that the speaker is balanced, minimizing the mechanical vibrations produced during operation.

Further characteristics and advantages of the present invention will appear clearer from the indicative, and therefore non-limiting, description of an embodiment of a transducer for an acoustic speaker, an acoustic speaker and a method for producing the transducer.

This description will come? shown below with reference to the attached drawings, provided for indicative purposes only and, therefore, not restrictive, in which: - Figure 1 shows a perspective view of a transducer;

- Figure 2 shows a further perspective view of a transducer without mechanical transmission;

- Figures 3A, 3B and 3C show perspective views of the inside of the transducer;

- Figure 4 shows a sectional view of the transducer;

- Figures 5A and 5B show a sectional view and a top view of a further embodiment of the transducer;

- Figures 6A and 6B show magnetic field patterns;

- Figure 7 shows a sectional view of a known acoustic diffuser to which ? a mechanical transmission according to the present invention was retrofitted;

- The figure 8? a perspective view of an acoustic speaker in which ? place the transducer;

- Figure 9? a perspective view of an acoustic speaker in accordance with the present invention.

With reference to the attached figures, with 100 ? a transducer for an acoustic speaker ?C? has been indicated.

The translator 100 includes a coil 200 including a plurality of of 201 turns each lying on a respective lying plane? transverse to a longitudinal axis ?A?. The turns 201 are juxtaposed along the longitudinal axis "A".

In other words, the coil 200 winds along the direction determined by the longitudinal axis ?A? such that its turns 201 are parallel to each other.

The transducer 100 further comprises a ferromagnetic circuit 300 including a core provided with a central portion 300a around which the coil 200 is located. wrapped.

The ferromagnetic circuit 300 further includes an external lateral portion 300b located laterally to the coil 200 and at least partially surrounding the coil 200 itself.

As shown in Figures 4 and 5A-5B, the external lateral portion 300b? separated from the core by an air gap ?T? extended longitudinally.

The transducer 100 further comprises at least one magnet 400a located within the air gap ?T?. The 400a magnet? a permanent magnet, i.e. a magnetized body capable of creating its own magnetic field.

The 400a magnet? mobile along a movement direction ?M1? parallel to the longitudinal axis ?A?.

In more detail, the movement of the magnet 400a along the movement direction M1? induced by an excitation magnetic field generated by an excitation of (i.e. by the passage of current within) the coil 200.

In such a situation, when the transducer 100 ? mounted within an acoustic diffuser ?C? and the coil 200 is excited by an electrical excitation signal, an excitation magnetic field is generated. This excitation magnetic field interacts with the magnetic field of the permanent magnet 400a, inducing the latter to move along the movement direction "M1". The movement of the magnet 400a causes, in turn, an oscillation or translation of a radiator 30b of the acoustic speaker ?C? allowing the latter to produce a sound. In the preferred embodiment, the magnet 400a has a first end 400a? and a second end? 400a??.

The 400a magnet features a ?Sa? south pole. and a north pole ?Na? extending between the first extremity? 400a? and the second end? 400a?? parallel to the longitudinal axis ?A?.

As shown in figure 3A or 5A, in this situation, the magnet 400a substantially presents two opposing faces corresponding respectively to the south pole ?Sa? and to the north pole ?Na?.

When the 400a magneto? positioned in the air gap ?T?, one between the south pole ?Sa? and the north pole ?Na? ? entirely facing towards coil 200 while the other pole is facing the external side wall 300b.

In accordance with the present description, the ferromagnetic circuit 300 further includes an internal lateral portion 300c located laterally to the coil 200 and interposed between the coil 200 and the at least one magnet 400a.

The internal lateral portion 300c has a high permeability area? magnetic in proximity? of reel 200.

This area allows the field lines of the magnetic field of the magnet 400a to have a shape like that shown in figure 6B, i.e. it allows the magnetic field, when the coil 200 is not excited, to close within the internal lateral portion 300c and not within the nucleus, how will it come about? described in detail below.

In a possible embodiment, the high permeability area? magnetic? defined by a notch ?I? transverse to the longitudinal axis ?A? such as to divide the internal lateral portion 300c into an upper sub-portion 300c? and a sub-portion below 300c?? juxtaposed along a direction parallel to the longitudinal axis ?A? and defining respective pole pieces facing the air gap ?T?.

As shown in the sectional views of FIGS. 4 and 5A, the upper sub-portion 300c? and the lower sub-portion 300c?? of the internal lateral portion 300c? they can be made integral with the core and project from the central portion 300a towards the external lateral portion 300b. In this situation, the internal lateral portion 300c and the central portion 300a are shaped so that the ferromagnetic circuit 300 has a substantially H-shape in cross-section.

As shown for example in figure 4, the upper sub-portion 300c? and the lower sub-portion 300c?? cooperate to envelop almost all? of the reel 200 except the point where ? the carving ?I? was made.

In other words, the coil 200? embedded within (or covered by) the ferromagnetic circuit 300 except for the portion close to the notch ?I? which instead faces directly onto the air gap ?T?.

The presence of the carving? particularly advantageous as a zone of low reluctance (or high permeability?) is created such as to allow a development of the magnetic field in accordance with what is shown in figure 6B. In this situation, the at least one magnet 400a is in an equilibrium position within the air gap ?T?, i.e. in a position in which it is substantially entirely facing the notch ?I?. When a current is made to flow within the coil 200, it induces the excitation magnetic field which, by interacting with the magnetic field of the magnet 400a, induces its movement along the movement direction ?M1?.

In the preferred embodiment, the internal lateral portion 300c and/or the central portion 300a comprise a plurality of of plates aligned with each other along a direction transverse to the longitudinal axis ?A? (figure 3B).

With reference now to the embodiments illustrated in the attached figures, in figures 5A and 5B? shown is a possible embodiment of the transducer 100 in which the transducer 100 has a substantially radial development.

In this embodiment, the coil 200 has a substantially circular shape and is wrapped around the central portion 300a of the core. In this situation, the external lateral portion 300b has an annular shape defining an external ring surrounding the coil 200. The external ring is concentric to the coil 200 and forms with the latter a circular crown defining the air gap "T".

In this embodiment, as shown in figure 5B, the at least one magnet 400a also has an annular shape and defines a magnetic ring entirely surrounding the coil 200. The magnetic ring is positioned within the air gap ?T? such that one of the north pole ?Na? and the south pole ?Sa? is entirely facing towards the coil 200 for the entire circular development of the coil 200 itself, while the other pole is facing towards the external side wall 300b.

In other words, as shown in the section of figure 5A, the magnetic ring is divided, along a direction parallel to the longitudinal axis ?A?, into two parts respectively defining the north pole ?Na? and the south pole ?Sa? of the magnet 400a each of which ? entirely facing one of the coil 200 and the external side wall 300b.

In the example of figure 5B, the south pole ?Sa? ? facing coil 200 while the north pole ?Na? ? facing the external side wall 300b. The coil 200, the external ring and the magnetic ring are concentric and centered with respect to the longitudinal axis "A".

In this embodiment, the internal lateral portion 300c also has an annular shape defining an internal ring concentric with the external ring. The internal ring is located between the coil 200 and the magnetic ring.

In this situation, the notch ?I? does it develop annularly so as to define the upper sub-portion 300c? and the lower sub-portion 300c??.

As shown in figure 5A, also in this case, the upper sub-portion 300c? and the lower sub-portion 300c?? they protrude from the central portion 300a so as to cover and wrap the reel 200 above and below respectively. The upper 300c sub-portion? and the lower sub-portion 300c?? they then approach each other along a direction parallel to the longitudinal axis ?A? to at least partially wrap the sides (or walls) of the coil 200 facing the air gap ?T?.

In use therefore, when the coil 200 is excited by a current, an excitation magnetic field is generated which interacts with the magnetic field of the magnetic ring causing a movement of the same along the movement direction "M1". This movement causes a movement or oscillation of the radiator 30b of the acoustic speaker ?C? to which the transducer 100 ? associated.

Advantageously, the radial architecture of the transducer 100 described above allows to practically eliminate all the losses since the coil 200 ? entirely surrounded and enveloped by the ferromagnetic circuit 300.

With reference now to the embodiment of figures 2-4, the coil 200 has an elongated shape along a prevailing direction of development ?X? transverse to the longitudinal axis ?A?.

In this embodiment, the coil 200 includes a first rectilinear portion 200a parallel to the prevailing direction of development ?X? and a second rectilinear portion 200b facing the first rectilinear portion 200a and parallel to the prevailing direction of development "X".

The first and second straight portions 200a, 200b are joined together by respective connecting portions 200c which are rounded and transversal to the prevailing direction of development ?X? (Figure 3C).

In this embodiment, the external lateral portion 300b includes a first and a second part 300b?, 300b?? between them and placed laterally to the coil 200 symmetrically with respect to the longitudinal axis "A".

As shown for example in figure 3A-3C, the first and second parts 300b?, 300b?? of the external lateral portion 300b face respectively the first rectilinear portion 200a and the second rectilinear portion 200b.

The first and second parts 300b?, 300b?? of the external lateral portion 300b are spaced from the first straight portion 200a and from the second straight portion 200b of the coil 200 by the air gap ?T?.

In the preferred embodiment, the first and second parts 300b?, 300b?? of the external lateral portion 300b present, along the prevailing direction of development "X", substantially the same extension as the first rectilinear portion 200a and the second rectilinear portion 200b of the reel 200.

In this embodiment, the transducer 100 further comprises a further magnet 400b located within the air gap ?T? symmetrically to the magnet 400a with respect to the longitudinal axis ?A?. The additional 400b magnet is a permanent magnet.

As shown in figures 3B and 4, one of the magnet 400a and the further magnet 400b? interposed between the first straight portion 200a of the reel 200 and the first part 300b? of the external lateral portion 300b while the other between the magnet 400a and the further magnet 400b is interposed between the second straight portion 200b of the reel 200 and the second part 300b?? of the external lateral portion 300b.

The additional 400b magnet is mobile along a movement direction ?M2? parallel to the longitudinal axis ?A?.

More? in detail, when the coil 200 is energized to generate the excitation magnetic field, the movement of the further magnet 400b along the movement direction ?M2? is induced. In this situation, following the excitation of the coil 200, both the magnet 400a and the further magnet 400b are moved along the respective movement directions ?M1?, ?M2? (parallel to each other) to cause an oscillation of the radiator 30b of the acoustic speaker ?C? within which the transducer 100 ? mounted.

According to one aspect of this embodiment, the magnet 400a and the further magnet 400b respectively face the first and second rectilinear portions 200a, 200b of the coil 200 and have an elongated shape developing along respective axial directions parallel to the prevailing direction of development ?X ?.

According to a further aspect of the present embodiment, the first rectilinear portion 200a and the magnet 400a have the same axial extension and the second rectilinear portion 200b and the further magnet 400b have the same axial extension.

More? in detail, the coil 200? symmetrical and therefore? the axial extension of the first straight portion 200a is equal to that of the second rectilinear portion 200a and therefore the axial extension of the magnet 400a is? equal to that of the additional magnet 400b.

As shown in figure 3B, the magnet 400a and the further magnet 400b have the same pole ?Sa?, ?Na?, ?Sb?, ?Nb? facing reel 200.

In the figure cited above, the magnet 400a and the further magnet 400b both face the north pole ?Na?, ?Nb? to the coil 200. Alternatively, the magnet 400a and the further magnet 400b could both face the south pole ?Sa?, ?Sb? to coil 200 and, consequently, the north pole ?Na?, ?Nb? to the first and second parts 300b?, 300b?? of the external lateral portion 300b.

In this embodiment, the central portion 300a of the ferromagnetic circuit 300 and the portion of the internal lateral portion 300c have an elongated shape along the prevailing direction of development "X". In this situation, the notch ?I? ? transversal to the longitudinal axis ?A? and develops in parallel with the prevailing direction of development ?X?.

The carving ?I? ? such as to divide the portion the lateral portion an upper part 300c? and in a lower part 300c??.

As shown in 4, in this embodiment, the first and second straight portions 200a, 200b of the coil 200 are located alongside the central portion 300a of the ferromagnetic circuit 300 and are wound at the bottom and top by the upper and lower sub-parts 300c?, 300c?? of the internal lateral portion 300c.

In this situation, the first and second straight portions 200a, 200b of the coil 200 are immersed within the ferromagnetic circuit 300 substantially along their entire length while the connecting portions 200c protrude from the ferromagnetic circuit 300.

This aspect is particularly advantageous as it allows losses to be minimized and the efficiency of the transducer 100 to be increased.

In more detail, since the 200 coil develops almost entirely within the ferromagnetic circuit 300 ? It is possible to easily compensate (i.e. minimize) the efficiency losses caused by the connection portions 200c not immersed in the ferromagnetic circuit 300.

In use therefore, the magnet 400a and the further magnet 400b are found, if no current flows in the coil 200, in the equilibrium position, i.e. they are found against the notch ?I? made in the internal lateral portion.

When the coil 200 is excited by a current, an excitation magnetic field is generated within the ferromagnetic circuit 300 capable of disturbing the balance of the magnet 400a and of the further magnet 400b. In particular, the excitation magnetic field interacts with the magnetic fields generated by the magnet 400a and by the further magnet 400b, inducing the movement of the latter along the respective movement directions ?M1?, ?M2?. Consequently, the movement of the magnet 400a and of the further magnet 400b causes an oscillation (or translation) of the radiator 30b of the acoustic speaker ?C? within which the transducer 100 ? mounted allowing sound generation.

So that? the magnet 400a and the further magnet 400b move simultaneously along the respective movement directions ?M1?, ?M2?, the transducer 100 includes a support body 600 operatively connected to the magnet 400 and to the further magnet 400b to make the movement integral of the magnet 400a and of the further magnet 400b along the respective movement directions ?M1?, ?M2? when the coil 200 ? excited.

In accordance with one aspect of the description, the support body 600 has a closed and elongated shape along the prevailing direction of development ?X? in such a way as to define, symmetrically with respect to the longitudinal axis ?A? of the housing seats for the magnet 400a and the further magnet 400b (figure 2).

In use, at the moment of excitation of the coil 200, the magnet 400a and the further magnet 400b move simultaneously excited by the excitation magnetic field. Since the magnets 400a, 400b are bound to the support body 600, they drag the latter in a translation motion along the longitudinal axis "A". The support body 600 is then moved in reciprocating motion along a direction parallel to the longitudinal axis ?A? and therefore parallel to the movement directions ?M1?, ?M2? of the magnet 400a and of the further magnet 400b.

According to one aspect of the description, the support body 600 acts as an upper and lower limit switch for the magnets 400a, 400b in their lowering and raising movement along the movement directions ?M1?, ?M2?.

Advantageously, the support body 600 ensures that the travel of the magnets 400a, 400b along the respective movement directions ?M1?, ?M2? is such that the magnets 400a, 400b always remain immersed in the magnetic field generated by the excitation of the coil 200.

In other words, during their movement, i.e. in the use configuration, the magnets 400a, 400b always remain immersed in the excitation magnetic field.

According to one aspect of the present description, the transducer 100 comprises a containment shell 800 comprising two half-shells 800a, 800b mutually juxtaposed along the longitudinal axis ?A? and such as to define a containment volume (figure 3A).

Preferably, the half-shells 800a, 800b have a ?U? shape. and are each equipped with two flanges suitable for engaging the external lateral portion 300b of the ferromagnetic circuit 300.

In more detail, for example as shown in the embodiment of figure 3A, the containment volume is ? delimited at the bottom and top by the two half-shells 800a, 800b while ? delimited laterally by the external lateral portion 300b of the ferromagnetic circuit 300.

The 200 coil? integral with the half-shells 800a, 800b and fixed to them in such a way as to maintain a fixed position within the containment volume.

As shown in figure 1, the support body 600 is inserted into the containment volume for the parts engaged with the magnet 400a and the further magnet 400b while it is external to the containment volume for the remaining parts.

In accordance with an aspect of the invention, the transducer 100 further comprises a retaining band 700, preferably metallic, configured to prevent movement of the support body 600 transversally to the longitudinal axis ?A?.

In other words, the 700 retention band? configured to constrain the support body 600 to translate along a direction parallel to the longitudinal axis ?A? following a movement of at least one magnet 400a.

In accordance with one aspect of the description, the retention band 700? elastically deformable so that a movement of the support body 600 corresponds to a bending of the retaining band 700, how will this happen? described in detail below.

As shown in figure 1 or 2, the retention band 700 wraps the transducer 100, developing parallel to the prevailing direction of development ?X? and entirely surrounding the transducer 100.

In this situation, the support body 600 has a first and a second housing seat 600a, 600b (not visible) made on the ends? of the support body 600 opposed to each other along the prevailing direction of development ?X? and configured to stably accommodate the retention band 700.

In the preferred embodiment, the retention band 700 has a first portion 700a developing parallel to the prevailing direction of development ?X? along the first half-shell 800a between the first and second housing seats 600a, 600b. The retention band 700 also has a second portion 700b developing parallel to the prevailing direction of development ?X? along the second half-shell 800b between the first and second housing seats 600a, 600b.

The first and second portions 700a, 700b of the retention band 700 are pivoted to the first and second housing seats 600a, 600b, for example by means of screws.

The first and second portions 700a, 700b of the retention band 700 are also hinged to the first and second half-shells 800a, 800b, preferably in a central region thereof (figure 1), for example by means of screws. In this situation, when the magnets 400a, 400b are moved along the respective movement directions ?M1?, ?M2? and the support body 600 translates integrally with them parallel to the longitudinal axis ?A?, since the first and second portions 700a, 700b of the retention band 700 are pivoted to the first and second housing seats 600a, 600b and to the half-shells 800a, 800b, the retaining band 700 undergoes a bending.

Advantageously, the retention band 700 allows the movement of the magnets 400a, 400b along the respective movement directions ?M1?, ?M2? and, at the same time, avoids unwanted movement along different directions.

Advantageously, the retention band 700 also guarantees compactness and tightness of the entire transducer 100.

The transducer 100 which is the subject of the present description therefore has a modest size in the direction of movement of the at least magnet 400a (or, possibly, of the further magnet 400b if present).

The transducer 100 which is the subject of this description has a high electromechanical efficiency and good robustness as well as? a simplicity? of remarkable construction.

The transducer 100 which is the subject of this description has a moderate cost and a modest use of high-quality magnetic materials, as the transducer 100 allows the latter to work in the optimal point of the energy product of the magnet itself.

Furthermore, the subject of the description is a method for producing a transducer 100 for an acoustic speaker ?C?.

The method includes a step of preparing a transducer 100 comprising a coil 200 equipped with a plurality of of 201 turns each developing on a respective lying plane? transverse to a longitudinal axis ?A?. The turns 201 are juxtaposed along the longitudinal axis "A". The transducer 100 further comprises a ferromagnetic circuit 300 comprising a core provided with a central portion 300a around which the coil 200? wound and an external lateral portion 300b located laterally to the coil 20 and separated from the coil 200 by an air gap ?T?. The transducer 100 further comprises at least one magnetizable element.

In one possible embodiment, the transducer 100 comprises a pair of magnetizable elements opposite and symmetrical with respect to the longitudinal axis "A".

The method also includes a phase of positioning the magnetizable element within the air gap ?T? and a preparation phase, externally to the transducer 100, of an auxiliary magnetization circuit 10 configured to magnetize the magnetizable element.

In accordance with a possible embodiment, the auxiliary circuit 10 has an architecture like that shown in figure 6A. In particular, the auxiliary circuit 10 includes magnetization coils 11 capable of creating a magnetic field capable of magnetizing the magnetizable element.

The method then includes a magnetization phase of the at least one magnetizable element through an activation of the auxiliary magnetization circuit 10 in such a way as to create a permanent magnet 400a (or if there is a further magnetizable element, a further permanent magnet 400b ).

Advantageously, the possibility? to magnetize the magnetizable element once inside the transducer 100, allows to facilitate the assembly of the transducer 100 itself.

Furthermore, the subject of the description is an acoustic diffuser ?C? comprising a housing body 20.

In the embodiment shown, the housing body 20 has a circular shape in section. Alternatively, the housing body 20 can present, in section, any form.

The acoustic speaker ?C? it further comprises a transducer 100 placed within the housing body 20 (figure 8) and comprising a coil 200 and at least one magnet 400a, preferably a permanent magnet, movable with alternating motion along a movement direction ?M1? under the action of a magnetic field generated by the coil 200.

For example, the acoustic speaker ?C? can? comprising a transducer 100 in accordance with what has previously been described.

In the embodiment shown in the attached figures, the acoustic speaker ?C? includes a transducer 100 in accordance with the embodiment of figures 1-4.

The acoustic speaker ?C? it further comprises a radiating structure 30 comprising a suspension 30a connected to the housing body 20 and a radiator 30b connected to the suspension 30a.

The 30th suspension? configured to allow the radiator 30b to oscillate relative to the housing body 20.

In particular, the suspension 30a allows the radiator 30b to move with reciprocating motion along a longitudinal axis ?A? parallel to the direction of movement ?M1? of at least one magnet 400a.

In this situation, the 30b radiator is operationally coupled to at least one magnet 400a so that upon movement of the magnet 400a along the movement direction ?M1? parallel to the longitudinal axis ?A? corresponds to an oscillation of the radiator 30b along the longitudinal axis ?A? same.

More? in detail, the acoustic diffuser ?C? comprises a mechanical transmission comprising at least one actuation member 40 interposed between the at least one magnet 400a and the radiator 30b to move the radiator 30b in the opposite direction with respect to the at least one magnet 400a.

In other words, the actuation member 40 ensures that upon movement of the magnet 400a along the movement direction ?M1? in one direction, corresponds to a movement of the radiator 30b along the longitudinal axis ?A? in the opposite direction.

Advantageously, in this way, ? possible to balance the inertia forces acting on the acoustic speaker ?C? avoiding unwanted vibrations, how will it come? described below.

According to one aspect of the present description, the actuation member 40 comprises a pair of rotating members 41a, 41b pivoted to the transducer 100.

In greater detail, the rotating members 41a, 41b of the actuation member 40 are each pivoted at a connection point ?P? on the external side wall 300b of the ferromagnetic circuit 300 of the transducer 100 (figure 1).

In accordance with one aspect of the invention, at the connection points ?P?, the rotating members 41a, 41b are pivoted via pins. Preferably, ball or needle bearings are present interposed between the pins and the rotating members 41a, 41b.

Alternatively, the rotating members 41a, 41b are associated with the external side wall 300b via a compliant mechanism, i.e. a flexible mechanism that achieves the transmission of force and movement through the elastic deformation of the body of the actuating member 40. For example, the mechanism compliant can? be made in accordance with what is described in the Italian patent application No.

102021000001487 in the name of the same applicant, the content of which is? incorporated herein by reference. In the compliant mechanism described in that patent application, one end? of the compliant mechanism? connected to a passive radiant panel and another end? ? connected to a (compensation) mass; when this type of compliant mechanism is used in this solution, the first end? is connected to the radiator 30b (which in this case has an active role in the generation of sound waves) and the other end? of the compliant mechanism? connected (directly or indirectly) to the magnet 400a (and therefore to the masses integral with the magnet 400a); in particular, if there are two magnets, ? provided that there are two compliant mechanisms, one for each magnet.

In this situation, through an elastic deformation of the actuation member 40,? It is possible to transmit the movement (i.e. the translation) of the magnet 400a to the radiator 30b of the transducer 100 so that the radiator 30b is also moved.

Alternatively, ? It is possible to foresee a combination of compliant mechanisms and/or sliding or rolling systems. In this situation, is it possible to avoid introducing appreciable mass and keep the linearity characteristics unchanged? of the movement of the transducer 100.

In accordance with the embodiment shown in the attached figures, the rotating members 41a, 41b of the pair are juxtaposed to each other along an alignment direction transverse to the longitudinal axis ?A?.

In other words, the rotating members 41a, 41b of the pair are connected to the outer side wall 300b of the ferromagnetic circuit 300 so that their connection points ?P? are aligned along an alignment direction transverse to the longitudinal axis ?A? and parallel to the prevailing direction of development ?X?.

Preferably, the rotating members 41a, 41b of the actuation member 40 have a substantially round shape in which the connection point ?P? occupies a central position.

The rotating members 41a, 41b are counter-rotating with each other in response to the movement of the at least one magnet 400a along the movement direction ?M1?.

As shown in figure 1, the actuation member 40 also includes a connection body 42 integral with the radiator 30b.

The connection body 42 ? mobile of alternating movement along a direction parallel to the longitudinal axis ?A? to move the radiator 30b.

According to one aspect of the description, the connection body 42 is interposed between the rotating members 41a, 41b of the pair of rotating members and the radiator 30b.

As shown in figure 1, the rotating members 41a, 41b of the pair are arranged symmetrically with respect to the connection body 42.

In detail, the connection body 42? operationally connected to the rotating members 41a, 41b of the pair of rotating members in such a way that a rotation of the rotating members 41a, 41b corresponds to a movement (in alternate translation) of the connection body 42, how will it be? described below.

According to one aspect of the present description, the mechanical transmission constitutes a homokinetic inverter so that upon movement of the at least one magnet 400a along the movement direction ?M1? in a first direction, there corresponds to a simultaneous movement in a second direction, opposite to the first direction, of the radiator 30b along the longitudinal axis "A". In this situation, the excursion of the radiator 30b and the excursion of the at least one magnet 400a have a different amplitude.

In greater detail, the constant velocity inverter allows the translational movement of the magnet 400a in a first direction to be transformed into a translational movement of the radiator 30b in a second direction opposite to the first direction.

In use therefore, a translation of the magnet 400a in the first direction causes a rotation of the rotating members 41a, 41b and therefore a translation of the connection body 42 in a second direction opposite to the first direction. The movements of the magnet 400a and the radiator 30b are therefore to each other (simultaneous and) directed along the same direction (or parallel directions) but in opposite directions.

Note that the amplitude of these movements can be equal or different (i.e., to a translation of the radiator 30b of a first amplitude, there corresponds a translation of the magnet 400a of a second amplitude, in which the first amplitude and the second amplitude can be equal, or the first amplitude can be smaller or greater than the second amplitude) and what? it means that the transmission ratio given by the homokinetic inverter is ? unitary or not? unitary. In an example, the mass of the radiator 30b ? lower than that of the magnet 400a (and the transducer 100) and the amplitude of the excursion of the radiator 30a ? correspondingly greater than that of the magnet 400a.

This aspect is particularly advantageous as it is not necessary to have large excursions. It is necessary to excessively increase the mass of the transducer 100 or the radiator 30b.

In the preferred embodiment, the connection body 42? connected to each of the rotating members 41a, 41b of the pair by means of compensation plates 50 extending parallel to the longitudinal axis ?A?. The compensation plates 50 are at least partially flexible to compensate for movements of the connection body 42 along directions transverse to the longitudinal axis "A".

As shown in the attached figures, the rotating members 41a, 41b of the pair each have a connection point to a respective compensation plate 50 so that the latter develops between the connection point and the connection body 42.

In the embodiment shown in the attached figures, the actuation member 40 includes further compensation plates 50 configured to connect the at least one magnet 400a to the rotating members 41a, 41b of the pair.

In the embodiment shown in figure 1, in which the transducer includes the support body 600, the rotating members 41a, 41b of the pair are connected to it via respective compensation plates 50 so that a translation of the support body 600 corresponds to a rotation of the rotating members 41a, 41b.

In use, when current is passed within the coil 200 of the transducer 100, an excitation magnetic field is generated. This excitation magnetic field disturbs or modifies the magnetic field of at least one magnet 400a causing the alternate movement of the latter along the movement direction "M1".

In this situation, since the rotating members 41a, 41b of the pair are operationally connected to at least one magnet 400a, a movement of the latter corresponds to a rotation of the rotating members 41a, 41b around the connection points ?P?.

By rotating, the rotating members 41a, 41b transmit, via the compensation plates 50, the motion to the connection body 42 which translates along a direction parallel to the movement direction ?M1?. In particular, if the at least one magnet 400a is raised, the connection body 42 is lowered while, if the at least one magnet 400a is lowered, the connection body 42 is raised.

In other words, the rotating members 41a, 41b, by rotating, cause a reversal of the motion of the at least one magnet 400a such as to cause a movement of the connection body 42 (and therefore of the radiator 30b of the acoustic speaker ?C? connected to it) in the opposite direction.

Advantageously, through the mechanical transmission described above, ? It is possible to balance the forces in play in such a way as to create an inertially balanced system, free of mechanical vibrations generated by the movement of the system itself.

Advantageously, given that the mass belonging to the transducer 100? comparable with the mass of the acoustic coupling systems of the acoustic diffuser ?C?, ? it is convenient to use a mechanical transmission like the one described above, i.e. a transmission capable of reversing the motion and which allows the masses in play to be inertially opposed in such a way that the acoustic diffuser ?C? is balanced, minimizing the mechanical vibrations produced during operation. Advantageously, the transmission member 40 as described above avoids introducing non-linearity. in the transfer of movement and forces between the transducer 100 and the radiating structure 30.

In the preferred embodiment illustrated in the attached figures, the transducer 100 includes a further magnet 400b which moves simultaneously with the magnet 400a. The additional 400b magnet is reciprocating movement along a further movement direction ?M2? parallel to the movement direction ?M1?. In this situation, the mechanical transmission includes a further actuation member 60 placed between the further magnet 400b and the radiator 30b to move the radiator 30b in the opposite direction with respect to the further magnet 400b.

In accordance with a possible embodiment, the further actuation member 60 also constitutes a homokinetic inverter.

As shown in figure 1, the actuation member 40 and the further actuation member 60 are arranged symmetrically with respect to the transducer 100.

Furthermore, in use, since the magnet 400a and the further magnet 400b are movable simultaneously, the actuation member 40 and the further actuation member 60 are also movable simultaneously in accordance with the modality? described above for the implementing body 40.

In detail, when the coil 200 is excited by a current, it generates an excitation magnetic field such as to disturb the balance of the transducer 100. In this situation, the magnet 400a and the further magnet 400b move simultaneously along the respective directions of movement ?M1?, ?M2? in alternating motion (lifting and lowering) causing the rotation of the pair of rotating members 41a, 41b, 61a, 61b of each of the actuation members 40, 60.

The rotation of the rotating members 41a, 41b, 61a, 61b causes, in turn, the movement of the support bodies 42, 62 of each actuation member 40, 60. In particular, the support bodies 42, 62 are moved in the direction opposite to that of the magnet 400a and the further magnet 400b so that there is an inertial balance of the acoustic speaker ?C?. In this situation, the radiator 30b of the acoustic speaker ?C? it is moved simultaneously and together with the support bodies 42, 62 so that it is also moved in the opposite direction with respect to the magnets 400a, 400b.

Advantageously, as also illustrated in figure 7, the mechanical transmission can be applied as a retrofit to moving magnet transducers of prior art loudspeakers.

Furthermore, the invention concerns a method for extending the response to low frequencies of an acoustic speaker "C". The method includes a phase of preparation of an acoustic diffuser ?C? comprising a housing body 20 and a transducer 100 located within the housing body 20. The transducer 100 includes a coil 200 and at least one magnet 400a.

In accordance with a possible embodiment, the transducer 100? carried out as described above.

The acoustic speaker ?C? it further comprises a radiating structure 30 including a suspension 30a connected to the housing body 20 and a radiator 30b connected to the suspension 30a.

The 30th suspension? configured to allow the radiator 30b to move, in particular to move with reciprocating motion.

The acoustic speaker ?C? it further comprises a mechanical transmission comprising at least one actuation member 40 operatively interposed between the magnet 400a and the radiator 30b.

In the preferred embodiment, the actuation member 40? carried out in accordance with what is described above.

The method includes a generation step, via the coil 200, of an excitation magnetic field to move the magnet 400a with an alternating motion along a movement direction ?M1?.

Preferably, the excitation magnetic field is generated by passing current through coil 200.

The method then includes a step of transmitting the movement of the magnet 400a to the radiator 30b via the mechanical transmission.

In this situation, the method includes a step of moving the radiator 30b in reciprocating motion along a longitudinal axis ?A? parallel to the direction of movement ?M1? in the opposite direction with respect to the magnet 400a.

According to one aspect of the description, the mechanical transmission constitutes a constant velocity inverter. In this situation, the transmission phase includes a sub-phase of moving the at least one magnet 400a along the movement direction ?M1? in a first direction and a sub-phase of movement of the radiator 30b along the longitudinal axis ?A? in a second verse, opposite to the first verse. The movement phases are simultaneous with each other.

In this situation, the mechanical transmission defines a non-unitary transmission ratio in which the excursion of the radiator 30b has an amplitude different from the amplitude of the excursion of the magnet 400a. Alternatively, the mechanical transmission defines a unit gear ratio in which the excursion of the radiator 30b has an amplitude equal to the excursion amplitude of the magneto 400a.

The present invention achieves the intended objectives by eliminating the drawbacks that have emerged from the prior art.

In particular, the present invention provides a transducer and an acoustic speaker having a modest size in the direction of movement of the at least one magnet.

The present invention provides a transducer having high electromechanical efficiency and robustness.

The present invention provides a transducer that is easy to assemble.

The present invention provides an inertially balanced acoustic speaker even when working at low frequencies. The present invention provides an acoustic speaker with compact dimensions but with a high SPL value.

Claims (17)

1. Transducer (100) for a speaker (C), comprising: - a coil (200) including a plurality? of coils (201), each lying on a respective lying plane (?) transverse to a longitudinal axis (A), the coils (201) being juxtaposed along the longitudinal axis (A); - a ferromagnetic circuit (300), including: a core provided with a central portion (300a) around which the coil (200) is wrapped; an external lateral portion (300b) located laterally to the coil (200) and at least partially surrounding the coil (200), the external lateral portion (300b) being separated from the core by an air gap (T) extending longitudinally; - at least one magnet (400a) placed within the air gap (T) and movable along a movement direction (M1) parallel to the longitudinal axis (A), the magnet (400a) being a permanent magnet, the coil (200) being excitable in such a way as to generate an excitation magnetic field, to induce a movement of the magnet (400a) along the movement direction (M1). 2. Transducer according to claim 1, in which the ferromagnetic circuit (300) includes an internal lateral portion (300c) located laterally to the coil (200) and interposed between the coil (200) and the at least one magnet (400a), the one internal lateral portion (300c) presenting a high permeability area? magnetic in proximity? of the coil (200). 3. Transducer according to claim 2, wherein said zone is? defined by a notch (I) transverse to the longitudinal axis (A) such as to divide the internal lateral portion (300c) into an upper sub-portion (300c?) and a lower sub-portion (300c??) juxtaposed along a direction parallel to the longitudinal axis (A) and defining respective pole expansions facing the air gap (T). 4. Transducer according to claim 3, wherein the upper sub-portion (300c?) and the lower sub-portion (300c??) of the internal lateral portion (300c?) are made integral with the core and project with respect to the portion central (300a) towards the external lateral portion (300b), 5. Transducer according to any one of the preceding claims, wherein the at least one magnet (400a) has a first end? (400a?) and a second extremity? (400a??), the magnet (400a) having a south pole (Sa) and a north pole (Na), each extending between the first end? (400a?) and the second extremity? (400a??) parallel to the longitudinal axis (A). 6. Transducer according to any of the previous claims, in which the coil (200) has an elongated shape along a prevailing direction of development (X) transverse to the longitudinal axis (A) and in which the coil (200) includes a first portion rectilinear (200a) parallel to the prevailing direction of development (X) and a second rectilinear portion (200b) facing the first rectilinear portion (200a) and parallel to the prevailing direction of development (X). 7. Transducer according to claim 6, comprising a further magnet (400b) placed within the air gap (T) symmetrically to the magnet (400a) with respect to the longitudinal axis (A) and movable along a movement direction (M2) parallel to the axis longitudinal (A) and in which the external lateral portion (300b) includes a first and a second part (300b?, 300b??) aligned with each other and positioned laterally to the reel (200) symmetrically with respect to the longitudinal axis (A). 8. Transducer according to claim 7, in which the magnet and the further magnet (400a, 400b) respectively face the first and second rectilinear portions (200a, 200b) and have an elongated shape developing along respective axial directions parallel to the prevailing direction of development (X). 9. Transducer according to claim 7 or 8, in which the magnet and the further magnet (400a, 400b) have the same pole (Sa, Na, Sb, Nb) facing the coil (200). 10. Transducer according to any one of claims 7 to 9, in which the first rectilinear portion (200a) and the magnet (400a) have the same axial extension and in which the second rectilinear portion (200b) and the further magnet (400b) have the same axial extension. 11. Translator according to any of the previous claims from 7 to 10, comprising a support body (600) operatively connected to the magnet (400) and to the further magnet (400b) to make the movement of the magnet (400a) and of the magnet (400a) integral. further magnet (400b) along the respective movement directions (M1, M2). 12. Translator according to claim 11, comprising a retaining band (700) configured to prevent movement of said support body (600) transversely to the longitudinal axis (A). 13. Translator according to claim 12, wherein the retaining band (700) is elastically deformable so that a movement of the support body (600) corresponds to a bending of the retention band (700). 14. Translator according to any of the previous claims 1 to 5, wherein: - the coil (200) has, in section, a substantially circular shape; - the external lateral portion (300c?, 300c??) has an annular shape defining an external ring surrounding the coil (200); - the at least one magnet (400a, 400b) has an annular shape defining a magnetic ring surrounding the coil (200); the coil (200), the external ring and the magnetic ring being concentric and centered with respect to said longitudinal axis (A). 15. Translator according to claim 14 when it depends on claim 2, wherein the internal lateral portion has an annular shape defining an internal ring concentric with the external ring. 16. Acoustic diffuser (C) including: - a housing body (20); - a transducer (100) according to one or more? of the previous claims placed within the housing body (20); - a radiator (30b); - a suspension (30a) configured to allow the radiator (30b) to oscillate with respect to the housing body (20), in which the radiator (30b) ? operationally coupled to at least one magnet (400a) so that a movement of the magnet (400a) along the movement direction (M1) parallel to the longitudinal axis (A) corresponds to an oscillation of the radiator (30b) along said longitudinal axis ( TO). 17. Method for manufacturing a transducer (100) for an acoustic speaker (C), comprising the following steps: - preparation of a transducer (100) comprising: a coil (200) comprising a plurality? of turns (201) each developing on a respective lying plane (?) transverse to a longitudinal axis (A), the turns (201) being juxtaposed along the longitudinal axis (A); a ferromagnetic circuit (300) comprising: a core provided with a central portion (300a) around which the coil (200) is wrapped; an external lateral portion (300b) located laterally to the coil (200) and separated from the coil (200) by an air gap (T); at least one magnetizable element; - positioning of the magnetizable element within the air gap (T); - provision, externally to the transducer (100), of an auxiliary magnetization circuit (10) configured to magnetize the magnetizable element; - magnetization of the magnetizable element placed within the air gap (T), through activation of the auxiliary magnetization circuit (10) in such a way as to create a permanent magnet (400a).