FR2671445A1 - OMNIDIRECTIONAL SOUND SYSTEM. - Google Patents

Abstract

Omnidirectional loudspeaker arrangement which comprises a rotationally symmetric enclosure (1) provided with a loudspeaker (2) centred on the axis of symmetry (XX') and pointing axially towards the outside of the enclosure, and a distributor element or acoustic wave reflector (3) rotationally symmetric about the said axis of symmetry and arranged opposite the loudspeaker and connected mechanically to the enclosure. The distributor element delimits, with the enclosure, a rotationally symmetric space consisting on the one hand of a central volume (10) in front of the loudspeaker forming a compression chamber for acoustic waves from the audible spectrum which are produced by the loudspeaker, the cross-section (9) of the peripheral exit of the compression chamber being smaller than the surface area of the diaphragm (16) of the loudspeaker, and on the other hand of a horn of revolution (11) whose annular entrance (9) is constituted by the peripheral exit of the compression chamber and whose cross-section of revolution (14) increases from its annular entrance (9) up to its annular exit (12).

Description

i

  Omnidirectional sound system.

  The present invention relates to an omnidirectional sound device comprising an enclosure provided with a loudspeaker and an acoustic wave distributor element associated with the loudspeaker. Traditionally, loudspeakers have one or more loudspeakers oriented in the same direction. Due to the intrinsic properties of the propagation of acoustic waves, low frequency waves propagate omnidirectionally, that is to say dispersed in the space without there being a predominant direction of propagation, while the high frequency waves, on the contrary, propagate rather in a privileged direction This results in order to be able to take full advantage of the acoustic effects without losing the treble of the audible spectrum , that the listener must place himself in a sound system centered on the emission axis of the acoustic enclosure. As an indication, the audible spectrum consists of all the frequencies between 20 Hz and 20,000 Hz, and is schematically divided into three parts: the upper part or the treble corresponds to frequencies greater than 5,000 Hz; the middle part or the midrange corresponds to frequencies between 150 Hz and 000 Hz; and the lower part or the bass corresponds to frequencies below 150 Hz The acoustic waves produced by the

  speakers are normally located in the audible spectrum.

  To overcome the drawbacks of conventional loudspeakers, it has been envisaged to increase the spatial sound angle of the loudspeaker by using an acoustic wave reflector. In fact, an important property of acoustic waves is that the more the frequency increases, the more the reflection on a solid surface is important. It follows that using a reflector, it is easier to deflect by reflection the diffusion path of the treble than that of the bass. Concretely, the solution consisted of a

  sound system with symmetry of revolution around an axis with the built-in

  speaker centered on the axis The speaker is embedded in a closed spherical enclosure or in one end of an acoustic column comprising an acoustic tube labyrinth and the other end of which is open Opposite the speaker is mounted a reflector the reflection surface of which is generated by the rotation around the axis of symmetry of a parabola or hyperbola arc. In this way, the treble of the audible spectrum produced by the loudspeaker is reflected and guided by the reflector and covers a space of 3600 around the axis of symmetry and a sound angle.

up to 270.

  In addition to increasing the sound angle of the device in the treble, the reflector placed in front of the loudspeaker makes it possible to effectively suppress or reduce the turbulence of the air created directly in front of the loudspeaker in conventional systems and

  consequently improve the quality of the broadcast sound.

  However, the arrangement of the reflector to ensure omnidirectional treble diffusion requires that the loudspeaker be placed facing the reflector and not to the listener. Such an arrangement has no direct consequence on the diffusion of the bass which already has properties. omnidirectional On the other hand, with regard to

  medium, the acoustic performance is rather poor.

  Indeed, located between the treble and the bass, the mids can only be very partially reflected and only propagate very partially in an omnidirectional manner. As a result, the sound devices with reflector known up to now do not provide a effective reproduction of the midrange of the audible spectrum produced by the loudspeaker, yet the midrange is more used than the

  treble and bass in general.

  The object of the present invention is to overcome the above-mentioned drawback

  mentioned by making an omnidirectional sound system-

  particularly efficient for the entire audible spectrum,

especially in the mediums.

  The omnidirectional sound device, according to the invention,

  includes an enclosure with symmetry of revolution provided with a built-in

  speaker centered on the axis of symmetry and oriented axially towards the outside of the enclosure, a distributor or reflector element of acoustic waves with symmetry of revolution around the axis of symmetry

  arranged opposite the loudspeaker and mechanically connected to the enclosure.

  According to the invention, the distributor or reflector element delimits with the enclosure a space with symmetry of revolution consisting on the one hand of a central volume in front of the loudspeaker forming a chamber for compression of acoustic waves of the audible spectrum produced by the loudspeaker, the section of the peripheral outlet of the compression chamber being smaller than the surface of the diaphragm of the loudspeaker; and on the other hand, a pavilion of revolution whose annular inlet is constituted by the peripheral outlet of the compression chamber and whose section of revolution increases from its annular inlet to its

annular outlet.

  Preferably, the peripheral outlet of the compression chamber is constituted by a groove of revolution which represents

  an annular section throttle of the compression chamber.

  This groove of revolution can be located along the peripheral edge

speaker.

  According to one embodiment of the invention, the omnidirectional sound device further comprises one or more tweeters distributed regularly around the axis of symmetry and arranged in the compression chamber. The tweeters are loudspeakers which emit acoustic waves. Advantageously, in the upper part of the audible spectrum, the direction vector of the emitting face of the tweeters makes an angle less than 90 relative to the axis of

  symmetry to orient the tweeters towards the reflector.

  According to a particular embodiment of the invention, the reflector has a protuberance with symmetry of revolution centered on the axis of symmetry and directed towards the loudspeaker. At the end of the protuberance is mounted a support member in the form of star on each branch of which a tweeter is mounted It is also possible to mount the tweeters directly on the protuberance

  reflector in an appropriate orientation.

  Advantageously, the variation in the sections of revolution of the pavilion from its entry to its exit is subject to a growth law

  exponential, but which can also be hyperbolic or conical.

  The enclosure supporting the loudspeaker and which constitutes the load

  acoustic for low frequencies, can be of different types.

  In particular, it may be of the Helmholtz resonator type and tuned vent. It may include either a vent on the axis of symmetry, or several vents regularly distributed around the axis.

  of symmetry and located opposite the speaker.

  Preferably, the enclosure and the reflector are made integral with one another using rigid rods distributed uniformly around the axis of symmetry and along the annular peripheral outlet section of the compression chamber. manner, the area of said outlet section is further reduced by the

presence of stems.

  Of course the reflector and the part of the enclosure to delimit the pavilion of revolution must have a smooth surface so

  improve the reflection characteristics of acoustic waves.

  The enclosure and the reflector are preferably made of light material to reduce the weight of the device of the invention, for example by

  rigid plastic or aluminum.

  The invention will be better understood on studying the description

  detail of an exemplary embodiment taken by way of non-limiting example and illustrated by the single appended drawing representing an axial section

  schematic of the device of the invention.

  According to the single figure, the omnidirectional sound device according to the invention comprises an enclosure 1, a loudspeaker 2, a distributor or reflector element 3 of acoustic waves and several tweeters 4 The loudspeaker 2 is embedded in the wall 5 of enclosure 1 by means of an annular support rim 6

  around the peripheral edge of the speaker 2.

  The loudspeaker 2 is oriented vertically upwards, its axis XX 'constituting the common axis of symmetry of the enclosure 1 and the reflector 3 The enclosure 1 has a vent 7 in tubular form directed towards the interior of the 'enclosure 1 and located coaxially to the axis of symmetry XX' The volume 8 enclosed by the enclosure 1 contributes to an amplification of the bass mainly around a resonance frequency granted by the vent 7 which constitutes a privileged output

  low frequency acoustic waves.

  The reflector 3 is mounted on the enclosure 1 by means of several

  rigid stems, not shown, regularly distributed around the top

  speaker 2 following an annular section 9 represented by mixed points. The reflector 3 thus mounted delimits with the wall 5 of the enclosure 1 a space with symmetry of revolution about the axis XX ', said space

  being subdivided into two parts: a central volume 10 opposite the upper

  speaker 2 and a pavilion of revolution 11 around the central volume 10.

  The separation limit between the central volume 10 and the pavilion 11 is represented by the annular section 9 which constitutes both the peripheral outlet of the central volume 10 and the entrance to the pavilion 11 The annular exit 12 from the pavilion 11 is constituted by a annular section formed between the outer edge 13 of the reflector 3 and the enclosure 1, said section being generated by the revolution around the axis XX 'of a straight line representing the distance between the outer edge 13

of the reflector 3 and the enclosure 1.

  According to the invention, the section of revolution 14 generated by the revolution around the axis of symmetry XX 'of a line segment representing the distance from a point 15 on the reflector 3 and the enclosure 1 The variation of the revolution section 14 of the pavilion 11 from its entry 9 to its exit 12 undergoes a monotonous growth law, preferably exponential Thus, the entry 9 of the pavilion 11 has

  the weakest section of the pavilion.

  According to the invention, the section 9 of the entrance to the pavilion 11 also constitutes the peripheral outlet of the central volume 10 and must be less than the surface of the membrane 16 of the loudspeaker 2, so as to be able to create a compression chamber in volume 10 for acoustic waves, especially in midrange and part of

serious.

  The combination between the compression chamber 10 and the horn 11 has the effect of increasing the acoustic efficiency of the midrange and the bass, and thus obtaining an amplification of the acoustic waves corresponding to the output 12 of the horn 11 The interior surface 17 of the reflector 3 as well as the outer surface 18 of the enclosure 1 delimited by the inlet 9 and the outlet 12 of the pavilion of revolution 11 are smooth so as to be able to ensure good reflection of the acoustic waves Thus the treble and midrange and possibly a part of the bass is guided by the internal surface 17 of the reflector 3 and the external surface 18 of the enclosure 1 towards the exit 12 of the pavilion of revolution 11 N must be added to this the bass from the vent 7 of the enclosure 1 In this way the device of the invention provides an omni-directional sound system around the axis XX 'with a high efficiency, in particular for mediums. The sound area is thus located at the bottom of the device, the extent of which is approximately delimited by a frustoconical surface extending

  tangentially the reflector 3 downwards.

  Concretely, the midrange and part of the bass produced by the speaker 2 first undergo compression in the compression chamber 10 before crossing the annular groove 9 which constitutes the peripheral outlet of the chamber and whose annular section is smaller than the surface of the diaphragm 16 of the loudspeaker 2 The corresponding waves then penetrate into the pavilion 11 whose increasing sections ensure the adaptation between the high radiation impedance of the annular groove and the low acoustic impedance of the air at exterior of the pavilion In this way the performance in

  midrange and some of the bass is greatly increased.

  With regard to the treble emitted by the speaker 2, the compression chamber 10 does not provide an increase in

  significant yield in this part of the spectrum.

  In order to increase the diffusion power in the treble, the invention provides one or more tweeters 4 of small dimensions mounted on a support member 19 which is made integral with the end of an axial protuberance 20 of the reflector 3 When several tweeters are used the support 19 is in the shape of a star with as many branches as there are tweeters 4 to support The emitting face 21 of the tweeters is preferably oriented towards the interior surface 17 of the

reflector 3.

  After a first reflection on the central part of the interior surface 17, the treble leaves the compression chamber 10 to then be optionally reflected by the exterior surface 18 of the enclosure 1 and / or the interior surface 17 of the reflector 3 before crossing the exit 12 The sum of the emissive surfaces of the tweeters 4 being very much less than the section of the annular groove 9, no compression effect is exerted by the chamber 10 for the

  acoustic waves from these tweeters.

  In this example, the reflector 3 and the wall 5 of the enclosure 1 are generated by the rotation about the axis of symmetry XX ′ of an arc of curve whose radius of curvature varies regularly Other forms of generating curves , such as straight segments or arcs of a circle can also be used It is preferable to make the reflector 3 anti-resonant so as to avoid parasitic acoustic effects One solution consists in covering the external surface 22 of the reflector with an absorption coating acoustic, for example

made of rubber.

  In practice, the power supply of the built-in

  speaker 2 and tweeters 4 is produced by means of an electric cable axially passing through the protuberance 20 of the reflector 3 The omnidirectional sound system according to the invention can be used both in suspension along the axis of symmetry XX ′, as well as in position

  inclined by means of a suitable support.

Claims (8)

  1 omnidirectional sound system comprising an enclosure (1) with symmetry of revolution provided with a loudspeaker (2) centered on the axis of symmetry (XX ') and oriented axially towards the outside of the enclosure, and a distributor or reflector element (3) of acoustic waves with symmetry of revolution about said axis of symmetry arranged opposite the loudspeaker and mechanically connected to the enclosure, characterized in that the distributor element (3) delimits with l enclosure a space with symmetry of revolution consisting on the one hand of a central volume (10) in front of the loudspeaker forming a compression chamber of acoustic waves of the audible spectrum produced by the loudspeaker, the section (9) of the peripheral outlet of the compression chamber being smaller than the surface of the diaphragm (16) of the loudspeaker, and on the other hand of a pavilion of revolution (11) whose annular inlet (9) consists of the peripheral output d e the compression chamber and whose section of revolution (14) increases from its annular inlet (9) to its annular outlet (12).   2 Device according to claim 1, characterized in that the peripheral outlet (9) of the compression chamber (10) is constituted by a groove of revolution which represents a constriction   of annular section of the compression chamber.   3 Device according to claim 1 or 2, characterized in that the peripheral outlet (9) of the compression chamber (10) is   located along the peripheral edge of the speaker (2).   4 Device according to one of the preceding claims,   characterized by the fact that it further comprises one or more tweeters (4) distributed regularly around the axis of symmetry (XX ') and arranged in the compression chamber (10), the directing vector of the emitting face (21 ) tweeters making an angle less than 90 relative to the axis of symmetry, so as to orient the tweeters towards the distributor element (3).   Device according to claim 4, characterized in that the reflective element (3) has a protuberance (20) with symmetry of   revolution centered on the axis of symmetry (XX ') and directed upwards-   speaker (2), and that the tweeter (s) (4) are mounted either directly   either indirectly on the protuberance.   6 Device according to claim 5, characterized in that it further comprises a support member (19) star made integral with the protuberance (20) and each branch of which supports a tweeter (4).   7 Device according to one of the preceding claims,   characterized in that the enclosure (1) and the distributor element (3) are made integral with one another by means of several rigid rods distributed uniformly around the axis of symmetry (XX ') and following the annular section (9) of the peripheral outlet of the chamber compression (10).   8 Device according to one of the preceding claims,   characterized by the fact that the enclosure (1) comprises one or more vents (7) regularly distributed around the axis of symmetry (XX ') and   located opposite the speaker (2).   9 Device according to one of the preceding claims,   characterized by the fact that the section of revolution (14) of the roof (11) varies from the annular inlet (9) to the annular outlet (12)   according to an exponential growth law.   Device according to one of the preceding claims,   characterized by the fact that the internal surface (17) of the distributor element (3) and the external surface (18) of the enclosure (1) between the inlet (9) and the outlet (12) of the roof revolution (11) are smooth and that the outer surface (22) of the distributor element (3) is   provided with an acoustic absorption coating.