PL182794B1 - Inertial vibration transducer - Google Patents

Abstract

1. Inertial vibration transducer for excitation of vibrations of a panel membrane, capable of sustaining and transmitting input vibration energy in the form of distortion waves of at least one active area located transversely to the thickness, characterized in that it contains a driving coil assembly (13, 18), in which the coil (13) is rigidly attached to the cylindrical carcass (18) and the magnet set (15), placed concentrically in relation to the driving coil assembly and the elastic elements (19, 136) supporting the magnet set, adapted for axial movement of the magnet set in relation to the driving coil assembly, wherein the cylindrical carcass (18) is adapted to be rigidly attached, by means of adhesive joints (16,20), directly to the panel diaphragm (2) excited to vibration in one of the predetermined, privileged positions of the transducer elements (9) in this area, to excite vibration, resonance and spread the vibration components of the resonant mode in at least one area and emit sound during resonance. Fig 3 PL PL PL PL PL PL PL

Description

The present invention relates to an inertial vibration transducer, in particular for loudspeakers having panel-shaped elements that emit sound.

The transducer is described in detail in International Application Nos. WO97 / 09859, WO97 / 09861, WO97 / 09858. GB-A-2262861 discloses a panel loudspeaker including a multimode resonating element which is a sandwich unitary panel formed of two materials separated by a core having a transverse chamber structure. The panel has, in all directions, a ratio of bending stiffness (B) to the cube of the panel mass per unit area (μ) of at least 10. The loudspeaker includes the elements of the fixture that hold the panel or attach a support element thereto in a way that does not dampen vibrations. and an electromechanical actuator coupled to the panel diaphragm which induces a multimode resonance in the panel diaphragm in response to an electrical excitation occurring in the loudspeaker's operating frequency band. A method of calculating the position of the transducer is disclosed in our related international application No. WO97 / 09842.

US-A-4 506 117 MULTIPHONIE discloses an acoustic transducer comprising an inertial mass adapted to rigidly connect its base plate to a panel diaphragm to vibrate it.

The state of the art for the invention is also provided by our related PCT application No. WO97 / 09842, in which the physical properties, structure and arrangement achievable generally and / or specifically are disclosed. The panel elements are able to support and transmit the input vibration energy in the form of deformation waves of the active areas extending transversely to the thickness, often but not necessarily up to the edges of the elements. They are listed with or without the strain anisotropy. This is to allow the vibration components of the resonance modes to propagate in the above-mentioned regions, preferably for acoustic coupling with the surrounding air. The transducer has predetermined privileged locations. This is particularly true of active or moving parts which are actually active with respect to acoustic vibrations and the signals, usually electric, corresponding to such acoustic vibrations. The uses are shown in PCT Application No. WO97 / 09842. It describes elements such as passive acoustic devices without transducers, used to produce reverberation, acoustic filtering or the sound reinforcement of a space or room. It describes elements such as passive acoustic devices without transducers, used to produce reverberation, acoustic filtering or sound reinforcement in a space or room, active acoustic devices with transducers, such as belonging to a significant group of sound sources or loudspeakers converting a given input signal into sound, or microphones converting sound into other signals.

In particular, the invention relates to active acoustic devices in the form of loudspeakers.

The above-mentioned components mentioned in the above PCT applications are called distributed-mode acoustic heat sinks similarly and / or differently as set forth herein.

An inertial vibration transducer for vibrating a panel diaphragm capable of supporting and transmitting the input vibration energy in the form of deformation waves of at least one active area transverse to the thickness, according to the invention, is distinguished by the fact that it comprises a drive coil assembly in which the coil is rigidly attached to a cylindrical carcass and a magnet assembly arranged concentrically to the drive coil assembly and resilient elements supporting the magnet assembly adapted to the axial movement of the magnet assembly with respect to the drive coil assembly, the cylindrical carcass being adapted to be rigidly attached by

Adhesive joints directly to the vibration-excited panel diaphragm at one of the predetermined, privileged positions of the transducer elements in that region, to excite, resonate, and spread vibration components of the resonant mode in at least one region and emit sound during resonance.

The inertial vibration transducer is preferably provided with resilient elements made of elastomer and positioned opposite on opposite sides of the magnet assembly.

The inertial vibration transducer is preferably provided with caps closing the axial ends of the cylindrical carcass, the resilient elements being mounted on the caps.

The coil is preferably mounted on the inside of the cylindrical carcass.

The drive coil assembly is preferably adapted to be received in a suitably shaped cavity in the panel membrane.

The caps preferably include resilient elements. Each cap preferably comprises a compliant annular surrounding disc.

The inertial vibration transducer is preferably equipped with magnetic screens over the pads.

The drive coil assembly is preferably adapted to be rigidly attached to the surface of the panel diaphragm.

The magnet assembly preferably includes disc-shaped opposing pole pieces, the edge of one being positioned internally adjacent to the drive coil assembly and the edge of the other being formed in the shape of a flange adjacent to and surrounding the drive coil assembly.

The inertial vibration transducer is preferably provided with a resilient element between one of the pole shoes and the surface of the panel membrane.

Preferably, the magnet assembly consists of an opposing pair of magnets with a pole piece in between.

In another preferred embodiment, the inertial vibration transducer is provided with complementary magnet assemblies and push-pull drive coil assemblies on opposite sides of the panel diaphragm and with means that bond the magnet assemblies together.

The subject of the invention, in an exemplary embodiment, is explained in more detail in the drawing, in which fig. 1 shows a diagram illustrating the disclosed loudspeaker, fig. 2a - a partial section along the line AA of fig. 1, fig. 2b - an enlarged cross-section through the vibration emitting element in fig. Fig. 2a, Fig. 3 - sectional view of the first embodiment of the transducer, Fig. 4 - sectional second form of the transducer, Fig. 5a - sectional view of the third form of the transducer, Fig. 5b - sectional view of the fourth form of the transducer, Fig. 5c - fifth embodiment cross-sectional view of the transducer, and Fig. 6 is a cross-sectional view of a sixth embodiment of the transducer.

Referring to Fig. 1, it shows a panel loudspeaker 81 having a rectangular frame 1 supporting a resilient suspension 3 on its inner edge which supports the panel diaphragm 2. The transducer 9 is mounted entirely and exclusively on or in the panel diaphragm 2 at the top. a specific place determined by the values of the x and y coordinates. The method of calculating its position is known. The purpose of the transducer is to cause the panel diaphragm to vibrate, which in turn causes it to resonate and emit a sound.

The transducer 9 is driven by a signal from an amplifier, for example a music amplifier, connected to the transducer via connectors 28. The required operating parameters of the amplifier, such as input values and power, are perfectly normal, similar to those of ordinary cone types of loudspeakers. The sensitivity is at the level of 86-88 dB / W in room conditions. The load impedance of the amplifier has a dominant resistive component of 6 Ω, the power is 20-80 W. In cases where the diaphragm core and / or the sheathing are made of metal, they can act as a thermal heat sink and reduce the temperature of the transducer by dissipating heat from the coil in the transducer. which increases the load capacity.

Figures 2a and 2b are typical partial cross-sections of the loudspeaker 81 of Fig. 1. Fig. 2a shows that the frame 1, the resilient suspension 3 and the panel membrane 2 are joined together by respective adhesive joints 20. Suitable framing materials are lightweight frames. for example picture frames of extruded metal, for example aluminum alloys or plastics. Suitable materials for resilient suspensions are resilient materials such as foam rubber and foamed plastics. Suitable adhesives for the joints are epoxy, acrylic and cyanoacrylate.

Figure 2b shows an enlarged view that the panel membrane 2 is a rigid panel of a lightweight structure with a core 22, e.g. of plastics or similar structures with cells arranged transversely to the plane of the membrane and closed by opposite planes 21, for example paper, cardboard, plastic, metal foil or sheet metal. The surfaces are made of plastics, they can be reinforced with fibers such as carbon, glass, Kevlar or those we know will increase the elastic modulus of the panel membrane.

The proposed materials for the outer covering include carbon, glass, Kewlar, Nomex, Aramid, fibers with various positions and weaves, similar to paper, paper laminates, melamine and various synthetic films with a high modulus of elasticity, such as Mylar, Kaptan, polycarbonate plastics, phenolic, polyester or the like and fiber-reinforced plastics, metal foils or sheet metal. Examination of the Vectra type thermoplastic liquid crystal polymer shows that it can be useful for injection molding extremely thin coatings or thinner coatings with a diameter size of up to 30 cm. This material has the property of self-forming it into an oriented crystal structure oriented in the injection direction most favorable to propagating high frequency vibration energy from the feed point to the edge of the panel membrane.

Additionally, such molding of thermoplastics allows for a great deal of choice in the positioning of elements such as grooves and rings, which in turn allows for the exact and appropriate positioning of parts of the transducer, for example the coil and the magnet suspension. The admixture of a weaker material to the core causes a favorable local increase in the density of the coating layer, e.g. in a ring with a diameter of 150% of the value of the transducer diameter, which is aimed at strengthening this area and more advantageously transferring the vibration energy to the panel membrane. Due to the use of lightweight materials with a foam structure, the response to the high frequency signal will be improved.

The materials shown for the core layer have a honeycomb structure or are corrugated sheets of aluminum alloys, Kewlar, Nomex, plain or laminated paper, and various synthetic plastic films, such as foam or cellulose materials, and even suitably low-density airgel metals. Several suitable materials for the core layer are capable of forming thin layers during the manufacturing process and / or otherwise have sufficient inherent stiffness to be used without the need for additional layers between the cover planes. The high-quality cellular material for the core layer is known as Rohacell and may be suitable for making a panel membrane without the need for any covering material. In practice, the aim is to obtain the greatest possible lightness and thinness suitable for the particular application, in particular to optimize the interaction of the transition area between the core and the covering layer.

Several preferred forms of panel diaphragm and its coverings employ metal and metal and metal alloy reinforcements, or alternatively carbon fiber reinforcements, in their construction. All of them, as well as structures using airgels or metal honeycomb cores, exhibit frequency shielding properties that should be important for several applications for which electromagnetic compatibility is important. Conventional panel or cone loudspeakers do not have the natural ability to be electromagnetically compatible.

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In addition, the preferred form of the piezo and electrodynamic transducer has a low level of emission of the electromagnetic field or random magnetic fields. A conventional loudspeaker produces a large magnetic field in an area of up to 1 meter, unless a specific compensator is used to reduce its value.

In applications where shielding is essential, electrical connections may be made to the conductive parts of the respective DML panel or to the conductive foams. Similar interfaces can be used for mounting on the edge of the panels.

The suspension 3 can damp vibrations at the edges of the panel membrane 2 to counteract excessive membrane movement. Additionally or alternatively, we can introduce further damping elements, e.g. inserts attached to the diaphragm at appropriate positions in order to dampen excessive deflections and hence to equalize the resonance values over the surface of the entire panel diaphragm. The inserts can be made of a bitumen-based material, such as are commonly used in conventional loudspeaker membranes, or they can be made of resilient or rigid sheets of polymeric material. Certain materials, especially paper and cardboard and some types of core, can be self-damping. Where required, the damping value can be increased by altering the structure of the panel diaphragm using resilient housings, more preferably than using rigid bonded housings.

Effective selective damping requires specific additives to the membrane, including the membrane itself and its coating. The edges and corners of the panel diaphragm are of particular importance for the dominant and less dispersed low frequency vibration modes. The fastening of the damping elements along the edges leads to the panel membrane being completely framed with the above-mentioned materials, even though its corners are relatively free. This is to broaden the frequency response from the low frequency side. This fixing can be done with glue or self-adhesive materials. Further forms of useful damping, especially for more refined effects and / or at medium and high frequencies, are brought about by applying an appropriate load or loads applied to the thin sheets of material at predetermined positions located in the center of the panel membrane area.

The panel membrane described above is bi-directional. The sound wave from the rear is not in phase with the wave from the front. This results in the benefits of overlapping sound waves in the room, the distribution of sound at the same frequency, the reduction of the effects of reflections and the effects of standing waves, which increases the feeling of a natural space when playing back recordings. While the emission from the panel membrane is highly non-directional, the percentage of information carried by the phase increases in the off-axis region. In order to increase the area of a well received stereo effect, it has an advantage to position the speakers like pictures at the height of a person. For a normally seated listener this will have the effect of improving the stereo effect in the off-axis region. Likewise, triangular two-sided geometry carries a further additional angular component with respect to the listener. We can thus obtain a good stereo effect.

There is another advantage for the audience group, compared to conventional loudspeakers. The scattering ability of the panel loudspeaker gives a loudness level that cannot be obtained by applying the law of decreasing sound intensity with the square of the distance with respect to the equivalent point source of sound. Since the decrease in intensity with increasing distance is much smaller than the law implies, as a consequence, for less well placed listeners, the area in which the panel loudspeaker obtains a much better stereo effect compared to conventional loudspeakers is larger. For this reason, off-axis listeners do not suffer as a consequence of the adjacent loudspeaker problem; first, an excessive increase in the intensity of the sound from the nearest loudspeaker and a corresponding decrease in the intensity of the sound from the further loudspeaker.

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Also advantageous are: flat size, light weight, attractive panel loudspeaker appearance, good sound quality and the requirement of only one driver and no crossovers to obtain the full range of sound from each panel diaphragm.

Figure 3 illustrates an embodiment of a moving coil transducer 9 adapted to be fully embedded within a rigid, lightweight panel membrane 2 of the type comprising a core 22 closed on two sides by cover planes 21 to induce deformation waves.

The transducer comprises a coil 13 embedded and secured, for example, by epoxy resin, in a cavity 29 in the core 22 of the panel membrane 2. The coil surrounds a cylindrical carcass 18. Thus, the coil 13 and carcass 18 are rigidly attached to the panel membrane 2.

The magnet assembly is disposed in a portion of the cavity 29 defined by the carcass 18. It comprises an opposing pair of magnets separated by a pole-forming member 14. The magnet assembly is mounted on the inner surface of the cover 21 of the panel membrane 2 by means of opposing compliant suspension members 19 of a rubber-like material, e.g. foam rubber. These elements are adhered to the magnet assembly and to the corresponding inner surfaces of the skin 21 of the panel membrane. In this way, the magnet assembly 14, 15 is mounted concentrically inside the coil and is able to perform an axial movement on its suspension 19.

The transducer 9 generates, by vibration, in the panel diaphragm 2 causing a local elastic deformation of the panel diaphragm corresponding to the axial movement between the magnet assembly and the coil. The moving effect is enhanced by the increased mass of the magnet assembly.

When operating at relatively high frequencies, where the mass of the magnet assembly is relatively large compared to the mass of the panel membrane, the inertia of the magnet assembly tends to keep the magnet assembly stationary and cause the panel membrane to vibrate appropriately.

Figure 4 shows an embodiment of a magnetoelectric transducer 9 similar to that shown in Fig. 3 and adapted to be mounted inside a rigid light panel membrane 2 of the type with a core 22 covered on both sides by a sheathing 21 to deform it. For ease of mounting in the panel diaphragm 2, the transducer 9 is formed as a module. As shown, the panel diaphragm has a corresponding recess 120 formed to accommodate the transducer 9.

The transducer consists of a coil 13 attached to the inner wall of the cylindrical carcass 18, e.g. in the right place. The assembly is made to fit into a recess 120 in the panel membrane 2 in the direction of arrow A as shown in the drawing. The transducer is attached to the recess with an adhesive.

The magnet assembly is mounted in a cavity 29 defined by the carcass 18. The assembly consists of a pair of opposing magnets 15 separated by a pole-forming element 14. The magnet assembly is fixed on end caps 119 of the carcass 18 by compliant suspension members 19 made of a rubber-like material, e.g. foam rubber that is glued to the magnet assembly and to the inner surface of the corresponding cap tip. Thus, the magnet assembly 14, 15 is mounted concentrically inside the coil 13 and is able to move axially on its suspension 19. The transducer 9 causes vibrations in the panel membrane 2 by vibrations which cause local elastic deformations of the membrane in an identical manner as described above in with respect to the embodiment of the invention described in Fig. 3.

The arrangement of the transducer 9 shown in Fig. 5a includes complementary, opposing elements on opposite sides of the panel diaphragm 2 to vibrate and resonate a rigid and light panel diaphragm 2 of the type that includes a core 22 surrounded on both sides by a sheathing 21.

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In this embodiment, both coils 13 are rigidly attached, for example glued, to the outer surface of the carcass 18 and together form an electroacoustic transducer rigidly attached, for example by epoxy welds 16, to opposite surfaces of the skin 21 of the panel membrane 2. The magnets 15 are surrounded by pairs. poles 14, one of which has a disc-shaped edge adjacent to the outer surfaces of each of the carcasses 18, and the other has a formed flange 162 on the edge surrounding the coil 13.

The generally cylinder-shaped connecting member 93 is adapted to freely traverse an opening 29 in the panel membrane 2. The connecting member 93 comprises opposing complementary portions each equipped with a head 95 clamping the axial ends of each of the transducers 9 and connecting them together. . Complementary portions of fastener 93 are joined by threaded portions 160, 161. The fastening element can be made of any suitable material, for example plastic or metal.

The transducer 9 of Fig. 5a is not rigidly pressed against the panel membrane 2 and is not in the opening 29, but is attached to the panel membrane by resilient washers 17 made of, for example, foam rubber, placed close to the opening 29 in the same way as shown. with reference to Fig. 3. Thus, due to its inertia resulting from the applied load, the transducer causes vibrations in the panel diaphragm.

The transducer 9 shown in Fig. 5b is largely similar to that shown in Fig. 5a. The difference is that it is attached to only one side of the panel membrane 2. The magnet assembly 14, 15 is attached to the surface of the panel membrane by an elastic suspension 17 made of, for example, rubber. The suspension is attached to the edge of the collar 162 of the outer pole piece 14.

Figure 5c shows a transducer 9 of the type shown in Fig. 5b intended to be easily attached to the surface of a panel membrane. The transducer 9 is attached by a carcass 18 and a resilient suspension 17 to a thin substrate 147 made of a material with an outer adhesive layer with which we can attach the transducer.

The transducer 9 shown in Fig. 6 has a small profile and is intended to be housed inside a thin panel membrane 2. The transducer comprises a cylindrical carcass 18 adapted to be attached, for example, glued, in a corresponding hole 29 inside the panel membrane 2. The coil 13 is attached to the inner the surface of the carcass 18, e.g. glued, and together form an electromagnetic transducer. The opposite axial ends of the carcass 18 are closed by flexible disc-shaped lug-type suspension elements 59 made of, for example, rubber or the like. Each has a ring-shaped ridge formed near its edge that forms 136, similar to that used in conventional cone drivers. The edges of the end caps 59 are attached to the axial ends of the casing 18, for example by clamping with adhesive or other suitable materials. The central parts of the caps 59 defined by the surrounding disk 136 contain therebetween a magnet assembly consisting of a pair of magnets 15 interlaced by pole pieces 14. The outer surfaces of the magnets 15 are glued or otherwise attached to the central parts of the caps 59. Thus, the magnet assembly 14, 15 is located concentrically with respect to the coil 13 and is able to make limited movements along its axis.

The magnet assembly is shielded by disc-shaped screens 121 mounted on resilient annular members 17 based on the panel diaphragm 2. They are intended to prevent or limit random magnetic fields surrounding the transducer.

While in the above-described transducer embodiments, the electro-acoustic transducer has been attached to the panel diaphragm 2 and the magnet assemblies have been movably mounted on the panel diaphragm, it is understood that such an arrangement may be inverted. The magnet assembly can be attached to the panel diaphragm and the electro-acoustic transducer can be movably attached. In this case, the magnet assemblies will be relatively light and the electroacoustic transducers will be relatively heavy to increase their impact.

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, 1/20/3 (\ I 2/20 22 <21/1 1 ^y and / ^k 21

Fig. 2a

Fig. 2b

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Fig. 3

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15 U 18 _z 21 ^k 13 147 ^ ^ 16

Fig.5c

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Fig. 6

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Publishing Department of the Polish Patent Office. Circulation of 60 copies

Price PLN 4.00.

Claims (13)

Patent claims 1. An inertial vibration transducer for exciting vibrations of a panel diaphragm capable of supporting and transmitting the input vibration energy in the form of deformation waves of at least one active area transverse to the thickness, characterized in that it comprises a driving coil assembly (13, 18), wherein the coil (13) is rigidly attached to the cylindrical carcass (18) and a magnet assembly (15) positioned concentric to the drive coil assembly and resilient elements (19, 136) supporting the magnet assembly, adapted to the axial movement of the magnet assembly with respect to the drive coil assembly, wherein the cylindrical carcass (18) is adapted to be rigidly attached, by means of glue joints (16, 20), directly to the vibrating panel diaphragm (2) at one of predetermined, privileged positions of the transducer elements (9) in this area, to stimulate to vibration, resonance and propagation of the vibration components of the reson mode ns signal in at least one area and sound emission during resonance. 2. An inertial vibration transducer according to claim The device of claim 1, characterized in that it is provided with elastic elements (19, 136) made of elastomer and positioned opposite on opposite sides of the magnet assembly. 3. An inertial vibration transducer according to claim The method of claim 1, characterized in that it is provided with caps (59, 119) closing the axial ends of the cylindrical carcass (18), wherein resilient elements (19, 136) are mounted on the caps. 4. An inertial vibration transducer according to claim The coil as claimed in claim 1, characterized in that the coil (13) is mounted on the inside of the cylindrical carcass (18). 5. An inertial vibration transducer according to claim The process of claim 1, characterized in that the drive coil assembly (13, 18) is adapted to be received in a suitably shaped cavity (120) in the panel membrane (2). 6. An inertial vibration transducer according to claim The method of claim 3, characterized in that the caps (59) comprise elastic elements. 7. An inertial vibration transducer according to claim The adapter of claim 6, wherein each cap (59) comprises a compliant annular surrounding the disc (136). 8. An inertial vibration transducer according to claim 6. Device according to claim 6 or 7, characterized in that it is provided with magnetic screens (121) over the caps (59). 9. An inertial vibration transducer according to claim A device as claimed in claim 1, characterized in that it is provided with a driving coil assembly (13, 18) adapted to be rigidly attached to the surface of the panel membrane (2). 10. An inertial vibration transducer according to claim 1. A device as claimed in claim 9, characterized in that it is provided with a magnet assembly (15) comprising opposing disc-shaped pole shoes (14), the edge of one of them being positioned internally adjacent to the drive coil assembly (13, 18) and the edge of the other being formed in the form of a flange (162) adjacent to and surrounding the drive coil assembly. 11. An inertial vibration transducer according to claim A device as claimed in claim 10, characterized in that it is provided with a resilient element (17) between one of the pole pieces and the surface of the panel membrane. 12. An inertial vibration transducer according to Claim A device as claimed in claim 1, characterized in that it is provided with a magnet set (15) consisting of an opposing pair of magnets (15) with a pole piece (14) in between. 13. An inertial vibration transducer according to claim 3. The method of claim 1, characterized in that it is equipped with complementary magnet sets and sets of driving coils for operation in a circuit On opposite sides of the panel diaphragm and the elements (93) binding the magnet assemblies together. * * *