EA002097B1 - Loudspeakers with panel-formacoustic radiating elements - Google Patents

Abstract

1. A loudspeaker comprising an enclosure, an acoustic radiator in the enclosure, a complaint suspension mounting the radiator in the enclosure for pistonic movement relative thereto and a transducer connected to the acoustic radiator, characterized in that the acoustic radiator is a panel-form distributed mode acoustic radiator, the transducer mounted on the acoustic radiator to excite bending waves in the radiator, causing it to resonate and producing an acoustic output, the loudspeaker comprises an air pressure varying means inside the enclosure thus providing the motion of the acoustic radiator relative to the enclosure 2. A loudspeaker according to claim 1, characterised in the air pressure varying means comprises an air pump. 3. A loudspeaker according to claim 2, characterised in that the air pump comprises a subsidiary enclosure, a pistonic driver mounted in the subsidiary enclosure and means coupling the interiors of the respective enclosures such that air pressure waves produced by motion of the pistonic driver are transmitted to the said enclosure. 4. A loudspeaker according to claim 3, characterised by acoustically absorbent means in the said enclosure and/or in the subsidiary enclosure or in both. 5. A loudspeaker according to any preceding claim, characterised in that the radiator comprises a lightweight cellular core sandwiching a pair of high modulus lightweight skins.

Description

The invention relates to loudspeakers, and more particularly to loudspeakers containing panel acoustic emitting elements.

State of the art

From UK application No. 2262861 A a loudspeaker made in the form of a panel is known, comprising a resonant multi-mode radiating element made in the form of a single three-layer panel formed by two shells of material with a cellular core placed between them with transversely directed cells, where the panel is made in such a way that has a bending stiffness ratio (B) in all directions to the cube of the panel mass per surface unit (μ) of the surface of at least 10, and also containing fixing means, with which the first panel is supported or attached to a support movably in the absence of damping, and electromechanical drive means connected to the panel which serves to create a multi-mode resonance in the radiating panels when applying to the loudspeaker an electric signal in the operating frequency range.

US Pat. No. 3,164,221 A (Rich) discloses a low frequency loudspeaker comprising a housing, an acoustic emitter in a housing, a flexible suspension securing the emitter in the housing for piston movement, and piston excitation means for changing air pressure in the housing to force the emitter to piston move .

US Pat. No. 3,247,925 A (Warnaca) discloses a low frequency loudspeaker with a resonance panel mounted on a chassis that is driven by an electromechanical converter also mounted on the chassis.

Disclosure of invention

In the embodiments of the present invention, elements are used whose properties, design and configuration of which are generally and / or specifically disclosed in the main provisions of our International Application, which is in the process of being considered simultaneously, with the same filing date, Publication No. AO 97/09842. Thus, such elements have the ability to maintain and propagate the supplied vibration energy through bending waves in the work area (work areas) passing across the thickness of the element (s), and often, but not necessarily, to the edges. The elements are made with or without anisotropy of bending stiffness with the possibility of the formation of vibrational components in the form of resonance modes distributed throughout the specified area (all specified areas), which facilitates acoustic communication with the surrounding air, and have predefined preferred places or sections for the transducer within the specified region, while, in particular, the active or moving parts of the elements are effective in creating acoustic vibrations in the indicated area (indicated areas), and signals, usually electric, corresponding to acoustic ones, cause such oscillations. In the International Application under simultaneous review, Publication No. AO / 97/09842 with the same filing date, cases of the use of such elements as in passive acoustic devices without converting means, for example, those designed to create reverb, to effect acoustic filtration, or to sounding of space or premises, as well as in active converting devices with converting means, for example, in extremely broadband sound sources or in loud voritelyah when fed input signals are converted to said sound, and also in microphones, in which sound is converted into signals of another kind.

This invention specifically relates to active acoustic devices in the form of speakers.

Elements such as those mentioned above are called acoustic emitters with distributed modes and their properties are implied as those in the aforementioned PCT applications, and / or otherwise, as specifically mentioned in this application.

The invention is a loudspeaker comprising a housing, an acoustic emitter in the housing, a flexible suspension, securing the emitter in the housing for piston movement relative to it, and means for changing the pressure in the housing to enable piston movement of the emitter, characterized in that the emitter is an element having the ability maintain and propagate the input energy of the oscillation by means of bending waves in at least one working region running across its t overshoot, to obtain component oscillations in the form of resonant modes distributed over the specified at least one region, and having for the transducer means predefined preferred locations or sections within the specified region, as well as containing a transducer installed completely and exclusively on the specified element in one of the specified locations or sections, to excite the oscillation of the element to cause its resonance with the formation of an acoustic emitter, which at resonance produces an acoustic signal. The means for changing the air pressure may comprise an air pump generator. The air pump generator may include an auxiliary housing, a piston exciter installed in the auxiliary housing, and means connecting the internal parts of the respective housings in such a way that air pressure waves generated by moving the piston exciter are transmitted to the specified housing. Sound absorbing means may be provided in said housing and / or in an auxiliary housing. The emitter may contain a lightweight cellular base, enclosed between a pair of light surface shells with a high modulus.

Brief Description of the Drawings

The invention is schematically illustrated by way of example with reference to the accompanying drawings, in which FIG. 1 - a loudspeaker with distributed modes of the type described and declared in our International Application, which is in the process of simultaneous consideration, publication No. νΌ 97/09842;

FIG. 2a is a partial section along line AA in FIG. one;

FIG. 2b is an enlarged cross section of a radiator with distributed modes of the kind shown in FIG. 2a, in two designs; and FIG. 3 is an embodiment of a distributed mode speaker in accordance with the present invention.

BEST MODES FOR CARRYING OUT THE INVENTION

Turning to FIG. 1, which shows a panel loudspeaker 81 of the kind described and claimed in our International Application pending at the same time, publication No. XVO 97/09842 with the same filing date, containing a rectangular frame 1 containing an elastic suspension in its inner contour 3, which supports sound-emitting panel 2 with distributed modes. Converter 9, for example, such as is described in detail in our International Applications under consideration at the same time, publications No. νΌ 97/09859, V) 97/09861, V) 97/09858 with the same filing date, is installed entirely and exclusively on sound-emitting panel 2 or in it in a predetermined place specified by the coordinates xi y, while the position of the place is calculated as described in our International Application undergoing simultaneous review, publication No. ^ 0/97/09842 with the same filing date, s the purpose of exciting bending n in the panel to cause the panel to resonance of the acoustic signal emission.

The transducer 9 is excited with a signal amplifier 10, for example, with an audio frequency amplifier connected to the transducer 9 via wires 28. The requirements for the load capacity and power of the amplifier can be completely normal, similar to the requirements for known cone speakers, taking into account the sensitivity order (86-88) dB / W when scoring the room. The total load resistance of the amplifier is mainly active at a resistance of 6 ohms, the required power is in the range (20-80) watts. When the core of the panel and / or surface shells are made of metal, they can be made so that they will act as a radiator of the converter to remove heat from the winding of the converter motor and, thus, improve energy transfer.

In FIG. 2a and 2b show typical partial cross-sections of the speaker 81 of FIG. 1. In FIG. 2a it is seen that the frame 1, the suspension 3 and the sound-emitting panel 2 are connected to each other by means of adhesive butt joints 20. As a frame, you can use a light frame, for example, a picture frame made of extruded metal, for example, aluminum alloy, or plastics. Satisfying suspension materials include resilient materials such as foam rubber and foams. Suitable adhesives for compounds 20 include epoxy, acrylic, cyanoacrylate and the like.

In FIG. 2b on an enlarged scale it is shown that the sound-emitting panel 2 is a rigid lightweight panel having a core 22, for example of rigid foam plastic 97, for example, of polyvinyl chloride with intermolecular bonds, or made in the form of a cellular matrix 98, i.e. a honeycomb matrix made of metal foil, plastics or equivalent with cells elongated across the plane of the sound-emitting panel, while the core is surrounded by opposite surface shells 21, for example, of paper, cardboard, plastics or of metal foil or metal sheet. When the surface shells are made of plastics, they can be reinforced with fibers, for example, carbon, glass, Kevlar (registered trademark) or equivalent, to increase the module, by a method that is essentially well known.

Test laminates for surface sheathing and reinforcement include carbon, glass, Kevlar (registered trademark), nomex (registered trademark), i.e. aramid and other fibers in the form of various layers and weaves, as well as paper, multilayer paper, melamine and various high-modulus synthetic plastic films, such as Mylar (registered trademark), captan (registered trademark), polycarbonate, phenol-based plastics , polyethers or related plastics, and in addition, fiber-reinforced plastics, etc., a metal sheet or foil. The study of the Vectra index for liquid-crystal thermoplastics showed that they can be used for injection molding ultra-thin surface layers or shells of a minimum size, for example, with a diameter of 30 cm. This material self-forms a crystalline structure oriented in the direction of injection; this orientation is preferable for good energy distribution at high sound frequencies from the point of excitation to the panel perimeter.

In addition, this molding of this and other thermoplastics allows the formation of mounting and alignment elements, such as grooves or rings, for the precise placement of transducer parts, for example, a moving coil and magnet suspension, using a mold. In addition, it was established by calculation that using some non-solid materials for the core it is advantageous to increase the thickness of the shell surface in a certain place, for example, in a section or in an annular space extending up to 150% of the diameter of the transducer to enhance this section and improve the transmission of vibrational energy to the panel. By this, the high-frequency response of soft foam materials can be improved.

When choosing layered materials for the core, the prefabricated structures of honeycomb panels or corrugations made of sheets or foil of aluminum alloy, Kevlar (registered trademark), nomex (registered trademark), ordinary or glued papers, and various films based on synthetic plastics were studied as well as from foamed plastics or foams or cellulosic materials, even from aerogel metals having a correspondingly low density. Some laminates suitable for the core have the self-cladding property used in their manufacture and / or otherwise have sufficient rigidity for use without lamination between the surface shells. Cellular material for the core, which has good characteristics, is known as Rojasel, and it can be used as a radiating panel without surface shells. In a practical sense, the task is to provide finite mobility and stiffness values corresponding to a specific purpose, including, in particular, optimization of contributions to the stiffness of the core structure, surface shells, and transition sections between them.

In some of the preferred designs of the sound-emitting panel, surface shells of metal or an alloy of metals are used or, alternatively, carbon fiber reinforcement is used. In both cases, as well as when the honeycomb core is made of an alloy such as airgel or metal, a noticeable effect of radio frequency shielding is observed, which is important when there are requirements regarding electromagnetic compatibility. Known panels or cone speakers do not have the ability to shield electromagnetic radiation.

In addition to this, preferred types of piezoelectric and electrodynamic transducers have a negligible level of electromagnetic radiation or scattering magnetic field. Conventional loudspeakers create a significant magnetic field up to a distance of 1 m, unless specific measures are taken to compensate for it.

When it is important to maintain shielding in practical applications, it is possible to connect to the conductive parts of the corresponding panel with metal shells; in addition, to fix the edge of the panel, it is possible to use electrically conductive foam material or a similar binder material.

Suspension 3 can dampen the edges of the sound-emitting panel 2 to prevent excessive movement of the edge of the panel. Additionally or alternatively, damping can be enhanced, for example, by means of pads attached to the sound-emitting panel in selected places both to limit excessive movement and to evenly distribute resonances across the sound-emitting panel. The pads can be made from a material based on bitumen, which is usually used in acoustic screens of loudspeakers, or from an elastic or rigid polymeric sheet material. Some materials, especially paper and cardboard, including some core materials, have the property of self-damping. When necessary, damping in panel designs can be enhanced by applying elastic adhesives after curing, instead of rigid adhesives after curing.

The specified effective selective damping involves a specific imposition on the sound-emitting panel, including its sheet material, of means permanently associated with it. Edges and corners can be especially significant for the main and less dispersed low-frequency modes of vibration of the sound-emitting panel. The attachment of damping means can cause the panel, together with its specified sheet material, to become completely framed by the system, although often the corners are left relatively free, for example, if it is necessary to work at lower frequencies. Attachments may be adhesives or self-adhesive materials. Other types of useful damping, especially those related to achieving finer effects and / or to reproducing mid and high frequencies, can be accomplished using the appropriate mass or masses attached to the sheet material in the middle of predefined locations of the specified area.

The sound emitting panel described above is bidirectional. Sound energy coming from the back is not much different in phase from the energy from the front. Therefore, the benefits of a total summation of the sound energy in a room, from a uniform frequency distribution of sound energy, from the suppression of reflection effects and standing waves are combined with the advantage of creating a natural sound space and atmosphere when playing a sound recording.

Although the radiation of the sound emitting panel is mainly non-directional, the proportion of phase information increases with a deviation from the axis. To improve the localization of the artificial stereo image, the loudspeakers are placed, like the pictures, at the height at which the person is usually located, compare the benefits of placement with a moderate deviation of the axes, at which the stereo effect is optimized for a normally located listener. Similarly, the triangular geometry (left / right) provides the listener with an additional angular component. Therefore, a good stereo effect is achieved.

Compared to the playback provided by a conventional speaker, there is an additional advantage for a group of listeners. The dispersive nature of sound emission inherent in a sound-emitting panel leads to the fact that the volume level does not obey the inverse square law for the distance from an equivalent point source. Since with decreasing distance the intensity decreases much more slowly than predicted by the inverse square law, therefore, for biased and incorrectly positioned listeners, the field of intensities of the panel speaker creates a better stereo effect compared to the field of ordinary speakers. This is because there are no two problems associated with the proximity of the nearest speaker for an off-center listener; this is, firstly, an excessive increase in the volume of the nearest speaker and, secondly, a corresponding decrease in the volume of the distant speaker.

Additional advantages that arise from the design of the loudspeaker in the form of a lightweight flat panel are in external attractiveness, in good sound quality, in the ability to have only one transducer and in the absence of intersection in the entire range of sound emission from each diaphragm of the panel.

In FIG. 3 shows yet another way of combining the piston mode and the resonant mode of the distributed modes in the loudspeaker 81. A lightweight rigid panel 2 with distributed modes of the kind shown in FIG. 1 and 2, forms the front wall of the housing 8 in the form of a box having side walls 135 and a rear wall 12, which are made of, for example, fiberboard, while the walls jointly define a cavity 155. The cavity 155 is provided with a panel 51 made of sound-absorbing material. A panel 51 of sound-absorbing material is provided to attenuate standing waves. The sound-emitting panel 2 is attached to the parts of the housing 8 by means of a flexible suspension 7, including for simulating the protective border of a conventional piston cone loudspeaker, and contains a transducer 9 of the type described in our international applications under processing No. XVO 97/09859, MO 97/09861, MO 97/09858 with the same filing date, installed completely and exclusively on the sound-emitting panel 2 in a predetermined location, as described in our simultaneous examination eniya MO 97/09842 International application with the same filing date, to excite bending waves in the panel.

The internal cavity 155 of the housing 8 is connected to a low sound frequency pump generator 11 by means of a tubular channel 90, i.e. with the inner part of the housing 185, containing the low sound frequency piston loudspeaker excitation unit 42, as a result of which low-frequency sound air pressure waves are supplied to the internal cavity 155 of the housing to enable the piston to move the sound-emitting panel 2 on its flexible suspension 7 to create a low-frequency sound signal . In addition, the transducer 9 causes the sound emitting panel to resonate to allow the panel to emit an audio signal at higher frequencies. The amplifier 1 is configured to supply an audio signal to a low-frequency pump generator and a transducer 9 for exciting a loudspeaker.

Claims (5)

CLAIM 1. A loudspeaker containing an acoustic emitter mounted in a housing by means of a pliable suspension that allows the acoustic emitter to move relative to the housing, and a transducer connected to an acoustic emitter, characterized in that the acoustic emitter is an acoustic emitter of a distributed mode, the transducer is mounted on the acoustic emitter and excites in an acoustic emitter, bending vibrations, which, causing a resonance in an acoustic emitter, both ensures, sound generation, wherein the loudspeaker includes means for adjusting the air pressure within the housing, thereby providing an acoustic radiator displacement relative to the housing. 2. The loudspeaker according to claim 1, characterized in that the means for changing the air pressure comprises an air pump generator. 3. The loudspeaker according to claim 2, characterized in that the air pump generator comprises an additional housing, a piston drive installed in the secondary housing, and means for transmitting air pressure from the secondary housing to the inside of the housing with the acoustic radiator installed. 4. The loudspeaker according to claim 3, characterized in that sound-absorbing means are installed in a housing with an installed acoustic emitter, or in an additional housing, or both. 5. The loudspeaker according to any one of paragraphs.1-4, characterized in that the acoustic emitter is made in the form of a panel with a light cellular core, enclosed between the two outer layers of the shell with a high modulus.