FR2713867A1 - Sound transfer system linking loudspeaker surface to listening point - Google Patents

Abstract

The system for delivering sound to a specific point includes a conduit (2) which has an internal bore whose diameter is very much less than that of the vibrating surface (3a) of a loudspeaker/transducer. The speaker is mounted with its axis aligned with that of the conduit. The conduit is made of a flexible material which is hermetically sealed to the transducer front. The conduit carries the acoustic pressure waves from the transducer to the listening point which is near to the other end of the conduit.

Description

 The present invention relates to a device making it possible, by its addition to one or more electromagnetic transducers, to produce an individual proximity sound system. This device is more particularly intended to be installed inside a headrest of a relaxation chair or vehicle seat while respecting the safety conditions. Individual proximity sound means the use of a sound emission device placed in the immediate vicinity of the listener without being in contact with the latter, at a limited distance and in line with the ears, leaving him free to head of all movements.

 Public address systems generally include rigid enclosures comprising electromagnetic transducers on their front faces. When these devices are made in small dimensions, there is a poor quality acoustic reproduction, especially in the reproduction of the lowest frequencies. On the other hand, when these devices are produced in larger dimensions, they offer better acoustic restitution, but have the drawback of being difficult to install near and in line with the listener's ears without hampering their movements and without risking injuring it in severe impacts.

 Other devices are known which include membrane transducers which are placed inside a vehicle headrest.

 Some devices include the solution of installing transducers on the front of an enclosure located at the rear of the listener, in a padded headrest, with direct diffusion of these behind the ears of the speaker. 'auditor. The set has the disadvantage of the situation of the emission points relative to the ears of the listener, a reproduction of low frequencies limited due to the reduced size of the transducers, the absence of a sound box, and the risk to injure the listener by the constituent elements of the transducers insufficiently separated from the listener.

 There is also known the solution of installing the transducers at the ends of a rigid enclosure acting as a headrest equipped with shells directing the sounds towards the listener. The assembly presents risks of injuring the listener by the constituent elements of the transducers, their supports and shells, which by definition are made of hard materials insufficiently separated from the listener. The set also has the disadvantage of the location of the emission points relative to the ears of the listener.

 None of the devices described above solves all of the problems posed by the drawbacks encountered in achieving close, stereophonic and quality individual sound inside a vehicle.

These disadvantages are as follows
- the location of the emission points of the pressure waves which must be optimally in the immediate vicinity and in line with the listener's ears, knowing that the emitting device is not in contact with it;
- compliance with safety conditions, in particular by the absence of risk of accidental injury caused by the constituent elements of the transmitting device;
- the dimensions of the constituent elements of the transmitting device, which must be as small as possible;
the quality of an acoustic reproduction obtained on the one hand by the linearity of the passband of the sound frequencies perceived at the listening points and on the other hand by the emission of secondary pressure waves, resonance harmonics, basic pressure waves;
- the mechanical and aesthetic conditions of its physical integration in the place of its use.

 By bandwidth is meant the spectrum of sound frequencies.

 The linearity of the passband is understood to mean the similarity, in amplitude value, of each frequency of the sound spectrum.

 The linearity of the passband of an acoustic device is understood to mean the ability of this device to reproduce the spectrum of sound frequencies, without altering the value in wave amplitude of each frequency in proportion to the others.

 The linearity of the passband, obtained at an optimum listening point, is understood to mean the restitution of the spectrum of sound frequencies, by an acoustic complex, without altering the value in wave amplitude of each frequency in proportion to the others. In other words, the restitution, in pressure waves, the most representative of the source signal that is the electric voltage applied to the transducer.

 It is these drawbacks that the present invention intends to remedy more particularly.

 The device according to the present invention comprises at least one conduit of any shape, the cross section of the internal bore of which is much less than the vibratory surface of the transducer, said conduit specifically composed of flexible materials being placed hermetically in front of the vibratory surface of the transducer and arranged for the purpose of transporting and adapting the pressure waves generated by the transducer in order to obtain at the optimum listening point located in the vicinity close to the emitting end of the conduit an acoustic perception as representative as possible of the electrical signal applied to the transducer.

The appended drawing, given by way of example, will allow a better understanding of the invention, the characteristics which it presents and the advantages which it is capable of providing:
Fig. 1 to 3 are schematic views illustrating the device according to the present invention.

 Fig. 4 is a curve representing, as a function of the frequency, the amplitude response of pressure waves of a vibratory membrane transducer known per se subjected to an oscillating electric energy of constant amplitude over the entire frequency range and free from the conduit of the device.

 Fig. 5 is a curve showing, as a function of the frequency, the value of the charges applied to the movement of the air and caused by the conduit of the device subjected to pressure waves of constant amplitude emitted by any generator over the entire frequency range .

 Fig. 6 is a curve illustrating, as a function of the frequency, the value of the charges applied to the movement of the air and caused by the conduit of the device subjected to pressure waves of amplitudes emitted by a transducer, the amplitude value of which frequency function is shown in fig. 4.

 Fig. 7 is a curve showing as a function of the frequency the general shape of the amplitude response of pressure waves obtained at the emitting end of the conduit of the device, the transducer being subjected to an oscillating electric energy of constant amplitude over the entire frequency range.

 Fig. 8 is a curve showing, as a function of frequency, the amplitude response of pressure waves, obtained at the optimum listening point, the device transducer being subjected to an oscillating electrical energy of constant amplitude over the entire range frequency.

 Fig. 9 and 10 are sections showing an example of installation of the device according to the invention.

 There is shown in fig. 1 to 3 a device 1 comprising a conduit 2 secured at one of its ends to a transducer 3 with a vibrating membrane 3a.

 The objective of the device 1 is to convert the vibrations of the transducer 3 subjected to an oscillating electric voltage into pressure waves of suitable amplitudes in order to obtain at the optimum listening point an acoustic perception as representative as possible of the electric signal applied to the transducer, in particular by a linearity of the pass band.

 The internal bore 2a of the conduit 2 has any shape either oval or circular depending on the shape and the external dimensions of the conduit 2. Likewise, the shape and the external dimensions of the conduit 2 are determined by the mechanical and aesthetic conditions of its physical integration in the place of its use and by the value of the most important pressure wave amplitude which it must convey.

 The receiving end 2b of the conduit 2, that is to say that located near the transducer 3, is hermetically fixed to the latter. The other end 2c called the transmitter has a concave profile for better diffusion of the pressure waves in the propagation medium.

In addition, the structure of the duct 2 is provided flexible and elastic, for example made of synthetic foam or the like so as to:
- mechanically absorb the energy from the amplitude losses of the pressure waves perpetrated within it;
- restore, by resonance phenomenon, harmonic pressure waves from basic pressure waves carried by the conduit;
- guarantee the absence of any dangerous contact for the auditor during major shocks.

 The section of the internal bore 2a of the conduit 2 is provided two to four times less than the section of the vibratory surface 3a of the transducer 3.

 The wall of the internal bore 2a is covered with a fibrous material 4 such as felt fabric or the like, of structure, shape and thickness adapted so as to increase the loads applied to the movement of the air at inside the duct (fig. 2). The device 1 comprises a conduit 2, the internal bore 2a of which is entirely or partially obstructed by light materials 5, which are not very compact, such as glass wool fiber or the like, so as to increase the loads applied to the movement of the air inside the duct 2. The light materials 5 can be placed anywhere inside the duct 2 and have a variable thickness depending on the desired loads.

 In Fig 3, the device 1 is shown, the conduit 2 of which is pierced with a multitude of parallel pipes 2d so that the sum of the sections of the internal pipes 2d of the pipe 2 is two to four times less than the section of the surface. vibration of the transducer (s) 3.

 Likewise, the pipes 2d can be covered with a fabric 4 and obstructed with a light material 5 made of glass wool fibers in order to increase the loads applied to the movement of the air inside the duct 2.

 The device 1 can comprise several transducers 3, which are associated with the same conduit 2.

 Thus the linearity of the passband, perceptible at the optimum listening point, is obtained by increasing the amplitude losses on the pressure waves of the highest frequencies, which pressure waves are easier to reproduce by the transducer. 3 and generally easier to propagate in the air. These losses are such that at the emitting end 2c of the conduit 2, the amplitudes of the pressure waves of the lowest frequencies are clearly favored.

The amplitude losses are obtained:
- On the one hand, by the loads applied to the movement of the membrane 3a of the transducer 3, themselves caused by the setting in motion of the volume of air located at the front thereof, said volume of air being constrained in its movement to borrow the internal bore 2a or the pipes 2d of the conduit 2.

 (Indeed, by the shape of its receiving end 2b and its reduced section, the duct 2 has a resistance to the displacement of the air located between the vibratory membrane 3a of the transducer 3 and its receiving end 2b).

 The small volume of air thus trapped offers little flexibility by compression phenomenon, forcing the transducer 3 to an additional effort. This effort represents an inertial load for the transducer 3 and thus limits the amplitude of the vibrations of its membrane. This effort increases with the amplitude of the pressure waves and their frequency.

 The charges thus applied increase very appreciably with the speed of movement of the air. A proportionally greater loss is observed over the amplitude of the highest frequency pressure waves.

 - On the other hand, by the charges applied to the movement of the air inside the duct 2 and obtained by the friction of the air on the surface of the constituent elements thereof.

 (In fact, the pressure waves, moving inside the duct 2, subject the air contained in the said duct to a wave displacement. This wave displacement is subjected, by friction to the materials 4 and 5 covering or obstructing the internal bore 2a or the pipes 2d of the conduit 2, at a load. The load, thus applied, increases very appreciably with the speed of movement of the air linked to the frequency of the pressure wave).

 In addition, the losses, explained above, are increased at the highest frequencies by the fact of the execution inside the conduit 2 of several achievements of periods of pressure waves before their diffusion by the end 2c of the conduit 2 in the place of propagation.

 Indeed, the pressure waves moving at the speed of sound in the air, the accomplishment of several pressure wave period can be observed over the length of the conduit, on the highest frequencies, increasing accordingly amplitude losses on these frequencies.

 We have represented in fig. 4 a curve illustrating as a function of the frequency F, the response, in amplitudes of pressure waves A, of a transducer 3 with a vibrating membrane known per se subjected to an oscillating electric energy of constant amplitude over the entire frequency range and free from the conduit 2 of the device 1. There is a loss of amplitude on the pressure waves A generated by the transducer 3 as a function of the increase in the frequency F.

 In fig. 5, a curve has been shown illustrating as a function of the frequency the value of the charges P applied to the displacement of the air caused by the duct 2, as a function of pressure waves of constant amplitude over the entire frequency range F emitted by any generator placed hermetically at the receiving end 2b of the duct 2. It is noted that the charges P applied to the movement of the air increase when the frequency F increases.

 In fig. 6, a curve has been shown representing, as a function of the frequency F the value of the charges P 'applied to the movement of the air and caused by the duct 2, as a function of pressure waves generated by the transducer 3, the value of which the amplitude as a function of the frequency F is shown in fig. 4. Thus the curve shows an almost absence of charge P 'applied to the displacement of air for the amplitudes of low pressure pressure waves, then an increase in these charges P' as a function of the increase in frequency F It is also noted that the value of these charges P ′ is progressively affected as a function of the frequency F by the drop in the amplitude of the pressure waves emitted by the transducer 3, submitted as above in FIG. 4 at an oscillating electric voltage of constant amplitude over the entire frequency range F.

 In fig. 7 a curve has been shown as a function of the frequency F, representing the response, in amplitudes A ′ of pressure waves obtained at the output of the device 1, the transducer 3 being subjected as previously in FIG. 4 at an oscillating electric voltage of constant amplitude over the entire frequency range. Note that the device 1 very significantly promotes the propagation within it of low frequency pressure waves compared to higher frequency pressure waves. The curve, shown in fig. 7, is specifically arranged for obtaining a linearity of the passband at the optimum listening point and represented in FIG. 8.

 Fig. 8 shows a curve, as a function of the frequency F, representing the amplitude response A "of pressure waves, obtained at the optimum listening point, the transducer 3 of the device 1 being subjected to an oscillating electric voltage of constant amplitude over the entire frequency range. We notice that we obtain a linearity of almost perfect pressure wave amplitude over most of the passband.

Note that the frequency range F for each of fig. 4 to 8 is distributed as follows
- from O to X we are in the low frequencies;
- between X and Y the frequencies are higher and called medium frequencies;
- from Y to Z we are in the high frequencies called treble.

 It should be noted that the device 1 allows, due to the corrections it makes, the absence of any enclosure at the rear of the transducer (s) 3 to which it is added.

 The maximum output of the acoustic assembly made up of the device 1 is not sought, the sound system being individual and of proximity.

 It is noted that the device 1 allows the restitution of harmonic pressure waves of resonance of the basic pressure waves, giving an acoustic volume effect to the user. Indeed, the creation of resonant frequency waves is obtained from the restitutions made by the flexible constituent elements of the conduit 2 subjected to the basic pressure waves generated by the transducer 3.

 We have represented in fig. 9 and 10 an embodiment of the device 1 described above and which is for the sake of clarity referenced 1 '. The device 1 'consists of a headrest 6 secured to a vehicle seat. the headrest 6 has two parallel parts 6a and 6b which are directed on either side of the listener's head so as to be in the vicinity of his ears. The headrest 6 comprises a metal upright 6c which allows on the one hand its fixing in the upper part of the backrest 6d of the seat and on the other hand its height adjustment relative to said backrest.

 The headrest 6 comprises two housings 6e and 6f which are crossed by the upright 6c while they are extended vertically to open out into the lower part of the headrest 6.

 Each housing 6e and 6f cooperates with a conduit 69 which is produced in the thickness of the headrest 6. The conduits 69 have the same characteristics as those described for the conduit 2 of the device 1.

Each conduit 69 extends into the parts 6a and 6b of the headrest to come out facing one another and in line with the ears of the listener.

 Inside each housing 6e and 6f is placed a transducer 3 'identical to that described in fig. 1. The transducers 3 'are fixed on the uprights 6c so that each of the vibratory membranes 3'a is turned towards the conduits 69.

The receiving end 6h of each conduit 69 is hermetically connected to each transducer 3 'so that the membrane 3'a remains free from any movement. The parts 6a and 6b of the headrest 6 are shaped so that the emitting end 6i of each conduit 69 is located at a certain distance from the ears of the individual and more precisely about 5 or 6 cm. the ends 6i are provided concave while the ends 6h are either flat, convex or concave depending on the loads applied to the movement of the desired air and according to the conformation of the transducers 3 '
It is obvious that for each transducer 3 'of different conformation, an adaptation of the shape of the receiving end 6h must be made if one wants to obtain the same loads applied to the movement of air.

The device 1 'thus designed allows the emission of pressure waves
A 'whose shape of bandwidth obtained at the emitting end 6i of each conduit 69 is shown in FIG. 7. This makes it possible to compensate for the phenomena of dispersion of the pressure waves in the air and thus obtain, at the optimum listening points, an acoustic reproduction having a passband linearity represented at A "in FIG. 8.

 The device 1 'avoids the risk of accidental injury due to a significant shock, since the headrest 6 is made of a flexible and deformable material which can cushion the head of the listener.

 The shape and dimensions of the device 1 'are mainly determined by the diameter of the transducers 3' and by the positioning of the emitting ends 6i of the conduits 69 at the optimum point of emission located at the right of the user's ears.

 It should moreover be understood that the above description has been given only by way of example and that it in no way limits the field of the invention from which one would not depart by replacing the execution details described by all other equivalents.

Claims (11)

R E U ~ E ~ N ~ o ~ '~ C ~ A ~ l ~' ~ o ~ N ~ S R E V E N D I C A T I O N S  1. Device for producing an individual proximity sound system of the kind comprising at least one transducer with a vibratory surface transforming electrical energy into a pressure wave, characterized in that it comprises at least one conduit (2, 69) for any shape whose cross section of the internal bore is much less than the vibratory surface (3a, 3'a) of the transducer (3, 3 '), said conduit (2, 69) specifically composed of flexible materials being placed hermetically in front of the vibratory surface (3a, 3'a) of the transducer (3, 3 ') and arranged in order to transport and adapt the pressure waves (A') generated by the transducer (3, 3 ') to obtain at the optimum point d listening in the vicinity near the transmitting end (2c, 6i) of the conduit (2, 69) an acoustic perception as representative as possible of the electrical signal applied to the terminals of the transducer (3, 3 ').  2. Device according to claim 1, characterized in that the duct (2, 69) consists either of an internal bore (2a) or of a multitude of parallel pipes (2d).  3. Device according to claims 1 and 2, characterized in that the conduit (2, 69) is provided in a flexible and elastic material such as foam or the like  4. Device according to claims 1 and 2, characterized in that the internal walls of the conduit (2, 69) and pipes (2d) are covered with a fibrous material (4) such as fabric, felt, or analogous in structure, shape and thickness adapted so as to increase the loads (P ') applied to the movement of air inside said duct and said pipes.  5. Device according to claims 1 and 3, characterized in that the conduit (2, 69) and the pipes (2d) are completely or partially obstructed by light materials (5) made of a material such as wool fiber of glass so as to increase the loads applied to the movement of air inside said conduit and said pipes.  6. Device according to claims 1 and 2, characterized in that the receiving end (2d, 6h) of the conduits (2, 69) and the pipes (2d) is of planar, convex or concave shape depending on the conformation of the transducer ( 3, 3 ') and obtaining more or less significant loads applied to the movement of air inside the duct.  7. Device according to claims 1 and 2, characterized in that the section of the internal bore (2a) or the sum of the sections of the internal pipes (2d) of the conduit (2, 6q) is two to four times less than the section of the vibratory surface of the transducer (3, 3 ').  8. Device according to claims 1 and 2, characterized in that the emitting end (2c, 6i) of the conduit (2, 69) and the pipes (2d) is of concave shape for better diffusion of the pressure waves in the medium of propagation.  9. Device according to claim 1, characterized in that the transducer (3, 3 ') is devoid of resonant acoustic enclosure.  10. Device according to any one of the preceding claims, characterized in that the shape, the dimensions and the external appearance of the duct (2, 69) are determined by the mechanical and aesthetic conditions of its physical integration in the place of its use, by the value of the largest amplitude which it must convey as well as by the optimum situation of its emitting end (2c, 6i) in line with the user's ear and the sufficient separation of the transducer (3, 3 ') and of the listener by distance and / or by the constituent elements of the device (1, 1').  11. Device according to claims 1 and 2, characterized in that it is more particularly intended to be placed inside a headrest (6) of a vehicle seat, in order to convey the noise emissions to the immediate vicinity of an auditor without being in contact with him.