EP2141691B1 - Adaptable noise creation device - Google Patents

Abstract

The device (1) has an actuator (3) arranged on a carrier plate (2) that is excited by vibrations. The plate is connected with an acoustic insulating material (9). Noise signals of the actuator are regulated by a control/regulation device (4) that is connected with the actuator. An amplifier (5) is arranged between the device (1) and the actuator. The plate is formed as a wall plate, ceiling plate, floor plate, room divider, furniture plate, cabinet plate and/or partition wall. A memory of a computer of the device (4) stores noise tone-characteristics that are changeable by a preset program. The insulating material is selected from mineral wool, gypsum foam, aluminum foam, polyurethane foam, melamine resin foam, hemp wool, non-woven fabric and/or felt material.

Description

The present invention relates to an acoustic, adaptive noise generating device which is capable of increasing the concentration ability of humans in acoustically difficult environments.

Area loudspeakers are long as such, for example from the DE 484 872 known. In the case of a flat loudspeaker, a voice coil functioning according to the electrodynamic principle is used, which is placed directly on a surface, initially of any size and thickness and made of a selected material, and mechanically fixed there. If the voice coil is electrically excited by a sound generator, then their vibrations are transmitted to the surface acting as a membrane and thus used themselves as a sound radiating surface. For an electroacoustic transducer of this type would be a variety given of uses. However, apart from a few exceptions, it has not been widely accepted until now, and this is due to its electro-acoustic properties, in particular its transfer function.

Functionally determining is above all the sound-radiating surface with its mechanical properties. This surface can only transmit tones or sounds if it vibrates mechanically. Apart from the clamping, ie the mechanical bearing and the location of the fixation of the voice coil on her, is preferably excited to bending vibrations plate-shaped surface in their vibration behavior in itself a relatively complex structure. While it is in a commercial loudspeaker according to the electrodynamic principle, even though only with compromise, still largely in the hand, to optimize the sound-emitting membrane in terms of their acoustic properties, this is not readily possible with flat panel speakers. Illustrated is this problem with an example: If the glass surface of a shop window, on which a voice coil is placed, are used as area loudspeakers, the material, shape and dimensions of the sound-radiating surface, including their restraint, are essentially fixed. The frequency response of the area loudspeaker in this example is thus substantially predetermined. Typically, the natural resonances of the area used for the sound radiation in this material and the dimensions of the shop window, a frequency response, which - simplified - is to be described by an excessive reproduction in the range of low tones and further by a Klirrneigung, lying on the influence of even in the auditory sector Attributed to self-resonances of higher order is. Corresponding characteristic nonlinearities also occur in other materials, such as wood or synthetic materials.

Such as out US Pat. No. 3,728,497 . US Pat. No. 3,636,281 or US Pat. No. 3,449,531 As has been known, efforts have been made to remedy the known disadvantages of the flat panel loudspeaker by means of constructive measures. Certain improvements could be achieved in this way, a fundamental solution, which would have opened up the flat-panel loudspeaker a wide range of applications, have not yet made the attempts made so far.

Other noise generating devices are off US 2008/0144850 A1 . US 5748748 . US 4098370 . EP 0 083 718 A1 . US 5692053 . JP 04113946 . EP 0 335 153 . US 5781640 such as JP 2005280546 A known.

From the psychoacoustics is known that it represents an increased degree of difficulty in intellectual work when the working environment has an increased noise level. Another aspect is the work in a room with several people sitting close together, when they are talking in parallel, as occurs, for example, in a call center. Here it is very disturbing when the neighbors' voices are clearly and clearly understood. Unintentional listening to foreign conversation content distracts one's ability to concentrate in intellectual work. If these voices are only vague to understand, then it improves the quality of work through improved mental concentration.

It is therefore an object of the present invention to provide a system or a cover that allows effective damping of disturbing sound, especially in difficult and reverberant acoustics.

This object is achieved with the features of claim 1. Here are the dependent claims advantageous developments.

According to the invention, an adaptive noise generation device in the form of a planar loudspeaker is thus provided, which comprises at least one actuator arranged on a support plate that can be excited by vibrations whose emitted noise signals can be adjusted via at least one control device connected to the actuator.

In this case, an amplifier for amplifying the signals coming from the control / regulating device is arranged between the control / regulating device and the actuator.

With regard to the preferred embodiments of the control / regulating device, several alternative embodiments are conceivable here. On the one hand, it is preferred if the control / regulating device comprises at least one manually adjustable switch. Thus, a noise preset can be switched on the user request, the amplitude is randomly adjustable.

However, it is also possible that the control device comprises a computer in whose memory different noise sound characteristics, which are variable via a predetermined program or freely selectable stored.

It is further preferred here if the computer is preceded by a microphone which records the prevailing acoustic signals and forwards them to the computer. In the computer, an analysis of these signals takes place, depending on the ambient volume, the outgoing noise signal is adjustable according to a predetermined algorithm.

In an equally preferred embodiment, the noise signals may be provided from a database. This database can also be arranged externally, so that a large number of adaptive noise generation devices can be supplied with the necessary signal by means of a database. The noise signals are transmitted from the database to the control unit.

In a preferred embodiment, the control unit is controllable via radio or via infrared. The control unit is equipped with a transmitter / receiver. The counterpart from which the control signals emanate may be a remote control or else a database or a computer.

According to the invention, the carrier plate is connected to an acoustic insulating material. Thus, on the one hand passive passive damping takes place, on the other hand, the existing sound can be further actively counteracted by the actuator. In particular, the acoustic insulation material is selected from mineral wool, gypsum foam, melamine resin foam, PU foam, aluminum foam, hemp wool, nonwovens and / or felting materials.

It is further preferred that the acoustic insulating material is covered with a fabric which can be excited electronically, so that the bespannstoff lights up, via which an illumination of the fabric is made possible. The lighting of the fabric can be varied over the entire color spectrum. In particular, the color of the light is controllable via a central processing unit, so that specific colors can be set separately or a continuous change over the entire color spectrum is possible.

The carrier plate according to the invention is designed as a wall plate, base plate, furniture plate, room divider, cabinet plate and / or partition.

The present invention will be further described with reference to the accompanying drawings, without limiting the invention to the parameters and specific embodiments shown in the figures.

In FIG. 1 an adaptive optical noise generating device 1 is shown, which consists of an excitable by vibration carrier 2 and a two-dimensionally connected to the support 2 acoustic insulation material. The insulating material 9 has certain acoustic properties, such as sound-absorbing properties, which makes the acoustics in rooms, whereby the reverberation time of a room is reduced by sound absorption. In the middle of the carrier 2, an acoustic actuator 3 is integrated.

For a person skilled in the technical acoustics is immediately evident that, inter alia, the properties of the sound-emitting carrier 2, its shape, the size of its surface, its thickness and above all its mechanical properties, but also the design of the actuator 3 and its local arrangement on the sound-emitting carrier 2 determine the acoustic properties of the flat-panel loudspeaker 1. Since, for example, completely different materials can be used for the sound-emitting carrier 2, a selection of materials already results Difficulty. Because it depends on whether the flat speaker 1, as in the case of wood materials, especially in the higher frequency range or on the other hand, such as glass, and plastics in the low-frequency range has a large attenuation, in the latter case, high frequency components excessive and thus rattles inclines. Because of this problem, area speakers, although the principles have long been known in a variety of per se possible applications not enforced because other electro-acoustic transducers are known whose frequency response is easier to correct.

The actuator 3 is in connection with an audio amplifier 5, which receives its audio signals, such as noise signals, from a control or regulating device 4. This control device may have, for example, a storage medium 10, which may be a CD player, for example.

The peculiarity here is that the system is adaptive and, depending on the difference of the applied on this vibrating plate 2 damping material 9 outputs different noise signals that takes into account the acoustic attenuation of the plate to output in each case an equal noise signal with the same character can.

The different noise signals can locally be switched over at the oscillating panel 2, for example via suitable switches 4a, the same sound characteristic always being able to be generated taking into account and correcting the acoustic damping properties of the material 9 applied to the panel 2 or the same subjective for all embodiments Sound perception is perceptible. Likewise, the amplitude of the acoustic signals via the switch 4a is adjustable.

Further, the control device 4 is connected, for example via a stationary USB port 8 with a computing unit or a database 6, via which a control of the control unit 4 and / or the amplifier 5 can take place. Similarly, an injection of acoustic signals, such as noise signals, which may be stored in the arithmetic unit or the database 6, in the control device 4 is possible. The control device 4 is preferably a microcontroller.

Likewise is in Fig. 1 presented the possibility to provide the insulation board with a fabric 11. This can possibly be excited to shine by corresponding lighting sources are available.

In FIG. 2 Another preferred embodiment of the acoustic adaptive noise generating device 1 is shown. Likewise, here the carrier 2 is provided with an acoustic insulating material 9 and equipped with an acoustic actuator 3. The peculiarity of the embodiment according to FIG. 2 is firstly to be seen in that there is a microphone 7, which detects the ambient volume, wherein the microphone 7 is in communication with a rating device 4b, which may be, for example, an electronic analysis unit, such as a computer. The computer unit 4b analyzes the frequency spectrum and / or the volume of the ambient acoustics detected by the microphone 7 and converts the detected information into control signals for the control or regulating device 4. Thus, via the computer unit 4b and the control device 4, the acoustic signals to be output by the actuator are actively controlled in terms of their frequency spectrum and their volume as a function of the ambient acoustics recorded by the microphone. This is done as already in FIG. 1 nor an amplification of the output from the micro-controller 4 signals via an amplifier 5. A further active control of the micro-controller 4 is possible via an external computer 6, for example, preferably with the micro-controller 4 via a radio network 8 ', 8th Thus, for example, the acoustic signals to be generated, such as noise signals, can be transmitted by radio from the computer center or database 6. The acoustic signals transmitted by the computer unit 6 can be present in a database stored on the computer unit 6. It is likewise possible for acquisition or storage and analysis of the detected acoustic signals evaluated by the microphone 7 and by the computer unit 4b to be performed by the central computer unit 6. Thus, a logging or storage of the current or even an averaged acoustic profile of the respective one possible to room to be sounded Likewise, via the external computer unit 6 there is the possibility that over the radio the locally adjusted sound characteristics can be overwritten or changed from a central point, for example with regard to unoccupied workstations or a control in the day / night rhythm.

Claims (11)

1. Adaptive noise generating device in the form of a flat-panel loudspeaker (1) comprising:

   - a carrier panel (2) excitable by vibrations and having a first side and a second side opposite the first side,

   - at least one actuator (3) arranged on the first side,

   - acoustic insulating material arranged on the second side and connected in a planar manner to the carrier panel (2),

   - at least one control/regulating device (4) connected to the actuator (3),

   - at least one amplifier (5) arranged between the control/regulating device (4) and the actuator (3),

   the noise signals of the actuator (3) which are to be emitted being adjustable via the control/regulating device (4), and the carrier panel (2) being a wall panel, ceiling panel, floor panel, furniture panel, room divider, cabinet panel and/or partition wall.
2. Adaptive noise generating device (1) according to Claim 1, characterised in that the control/regulating device (4) is formed by a microcontroller.
3. Adaptive noise generating device (1) according to Claim 1, characterised in that the control device (4) comprises at least one manually adjustable switch (4a) (noise preset).
4. Adaptive noise generating device (1) according to Claim 1, characterised in that the control device (4) comprises a computer (4b), in the memory of which are stored different noise sound characteristics which can be altered via a preset program or freely selectably.
5. Adaptive noise generating device (1) according to Claim 1, characterised in that the regulating device (4) comprises a computer (4b) and a microphone (7), and the noise emitted is adaptable according to a preset algorithm, depending on the ambient loudness.
6. Adaptive noise generating device (1) according to one of Claims 1 to 5, characterised in that the noise signals are provided by a data base (6).
7. Adaptive noise generating device (1) according to at least one of the preceding claims, characterised in that the control/regulating unit (4) is controllable via radio (8', 8").
8. Adaptive noise generating device (1) according to the preceding claim, characterised in that the control/regulating unit (4) is united with a computer unit (4b) and/or a data base (6) by an antenna (8') for transmitting and/or receiving noise signals and an antenna (8") for transmitting and/or receiving noise signals, in each case to form functional units, each of these groups being controllable via the computer unit (4b) and/or the data base (6).
9. Adaptive noise generating device (1) according to at least one of Claims 1 to 8, characterised in that the acoustic insulating material (9) is selected from mineral wool, gypsum foam, melamine resin foam, aluminium foam, polyurethane foam, hemp wool, nonwoven fabrics and/or felt materials.
10. Adaptive noise generating device (1) according to at least one of Claims 1 to 9, characterised in that the acoustic insulating material (9) is provided with a covering material (11) and this covering material itself can be excited to illuminate, so that an illumination of the covering material is adjustable.
11. Adaptive noise generating device (1) according to Claim 10, characterised in that the colour of the illumination is controllable via a central computer unit.

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