FR2883123A1 - Microphone device for e.g. respiratory mask of e.g. fireman, has transducer coated with rubber coating and placed on curved support, where rubber coating is plated by spring against wall of support and adopts shape of support - Google Patents

Abstract

The device has an acoustic vibration transducer (10) coated with a flexible and elastic rubber coating (14) and placed on a curved support (13) that is placed between an acoustic vibration source (S) and the transducer. A spring (12) plates the transducer on the support in an elastic manner. The rubber coating is plated by the spring against the wall of the support and adopts the shape of the support. An independent claim is also included for a protection mask or a helmet equipped with a microphone device.

Description

SOUND SENSING DEVICE, IN PARTICULAR FOR

Words uttered under a mask

  The present invention relates to a device for capturing sounds, including words emitted under a mask.

  Respirators are known for firefighters. These masks comprise a transparent visor which most often closes the mask to prevent the gases emitted by a fire from being inhaled by the wearer of the mask. These masks have at their base a gas filter cartridge which can also be connected to an air reserve cylinder. It is understood that under these conditions the speech emitted by the wearer of the mask is difficult to get out of the closed sphere thus formed.

  However, it is necessary that two mask wearers can communicate remotely. Indeed, in the case of firefighters, it is absolutely necessary that each of these can be located quickly to be rescued in case, for example, lack of air, loss of consciousness, discomfort, etc. The prior art first tried to pick up the sounds emitted by a helmet wearer, amplify them and transmit them to a transmitter.

  Microphone systems are known which are connected to a headset by means of a flexible support. These microphones are electroacoustic transducers that transform acoustic energy into electrical energy. They comprise an acoustic field sensitive element and a transducer producing an electrical signal. This electrical signal is then transmitted to an amplifier and to an emitter. These microphones are placed in front of the mouth and outside the helmet. They only capture the acoustic energy that is transmitted in the air and is stopped by the wall of the visor or helmet and can not capture the sounds emitted in a closed sphere or capture very difficult. Such a device is for example described in U.S. Patent No. 5,590,209, issued Dec. 31, 1996 to Setcom Corporation.

  We therefore sought to capture the vibrations emitted directly by the human body and no longer through the ambient air. A known device is to pick up the sounds emitted by the larynx. It is a laryngophone fixed on an elastic neckband. The laryngophone has a transducer that transforms the vibrations of the larynx into electrical signals. This laryngophone therefore has the advantage of being disposed inside a closed sphere such as a protective dry suit, a waterproof helmet isolated from the outside environment, or a gas mask. It also has the advantage of leaving your hands free. However, such a device has the disadvantage that it is awkward since it is worn around the neck, and must be located exactly on the larynx. Some people can hardly support an object on their larynx that can cause nausea. In addition, the positioning of the laryngophone must be done meticulously, which can cause a loss of time at the time of setting up the suit, the helmet, etc. In addition, this laryngophone can move easily during the various maneuvers unless it is tight on the neck.

  In the prior art, devices have been developed which capture the bone vibrations emitted when an individual utters words, called osteomicrophones. Such a device is described, for example, in US Pat. Nos. 3,787,641, issued January 22, 1974, to Setcom Corporation, US Pat. No. 3,723,670, issued March 27, 1973 to Dyna Magnetic Devices, the German utility model. No. G 89 03 602.6, filed March 22, 1989 by Ceotronics GmbH, European Patent Application 0 618 751, filed March 11, 1994, by Ceotronics GmbH, deemed withdrawn. These devices can be placed either on the skull vertex or on a temple. They certainly allow to transmit the words and leave the hands free of the wearer, but they require complicated systems of attachment of the osteomicrophone to the helmet. These attachment means are for example a system of straps and Velcro type strips. In addition, they require means to compress the microphone on the bones of the skull with a predetermined pressure and to move when the bones of the skull vibrate. The transducer follows the movements of the bones of the skull. The positioning of the osteomicrophone is therefore particularly important and it is difficult to keep it during the various maneuvers because it is inevitable that the skull of the wearer moves relative to the helmet. The capture of vibrations will be done more or less well. For example, the transducer may be a low mass, sensitive accelerometer of the type manufactured by Knowles Electronics Ins., Model No. BL1670 (see U.S. Patent No. 3,787,641, Column 2, lines 54-57).

  Other means have been sought to capture the vibrations emitted by speech; thus, U.S. Patent No. 6,493,451, issued Dec. 10, 2002 to Phone-Or Ltd., discloses a communication headset comprising an optical microphone which is placed on a fabric in front of the wearer's mouth. Such a device is complicated and involves additional microphone support elements.

  Many other documents describe helmets and communication systems of helmets. This huge number of documents shows that the problem has not been solved, namely, to provide a mask that allows to free the hands of the wearer, a quick implementation, without inconvenience for the wearer, a precise positioning to capture more precisely the vibrations emitted by the word, and this for a realization and a fabrication easy, fast and therefore less expensive.

  The invention solved this problem. Thus, the present invention relates to a microphone device characterized in that it comprises: an acoustic vibration transducer, a coating of said transducer of flexible material, means plating said transducer and its coating on a support and compressing the flexible material of said coating against the support; means for receiving said transducer provided with its coating; holding means on a support of said transducer with its coating, said receiving means and said plating means; said support being placed between the source S of acoustic vibrations and said coated transducer and remote from said source S. According to other features of the invention, said means for plating said transducer and its coating on the support are one or more springs placed between said receiving means and said coating; The vibration transducer (10) is placed between said support (13) and said resilient means; The means plating said transducer and its coating on the support are said holding means constituted by a clipping system on a rigid part of the mask, for example the rod; The support is placed in front of the mouth of a user and distant from it.

  The support is a mask visor; the support is a helmet visor, said visor being optionally liftable; Said microphone device is designed to withstand water, dust (according to the ISO IP68 standard), gases (for example, methane), explosive atmosphere (according to the ATEX standard).

  The microphone device is connected to an amplifier device and then to a transmitter system.

  The following description with reference to the accompanying drawings will provide a better understanding of how the invention can be practiced.

  FIG. 1 represents a firefighter mask comprising the device according to the invention (10).

  FIG. 2 shows a very schematic comparative study between a headset microphone (2A), a mask osteomicrophone (2B) and a mask microphone device according to the invention (2C).

  Figure 3 shows a schematic section of the device according to the invention.

  In Figure 1, there is shown a respirator can be used, for example, by firefighters. Such a mask 1 generally consists of a periphery 2 holding a visor 3 and a gas filter 4, and an air inlet 5. The periphery 2 of the mask 1 fits hermetically on the face of a human and is held on the head by means of straps 6, 7 which allow a strong support of the periphery 2 of the mask 1 on the face. All the front of the face is then isolated from the outside. The eyes, the nose and the mouth are thus protected from possible fumes of toxic gases (smoke, suspended particles, carbon monoxide, sulfuric acid, hydrochloric acid, etc.). an air inlet 5 connected to a compressed air cylinder (not shown) provides air to the carrier. Such a mask may be worn by a fireman, but also by other people such as volcanologists, speleologists, who may be in contact with atmospheres dangerous to the respiratory tract and the mucous membranes of the eyes and mouth. However, such necessary protection reduces the transmission of sound emitted by the mouth and subjects wearing such masks have real difficulties in communicating with each other. Indeed, the vibrations of the sounds emitted by the mouth of a subject are barred by the visor of the mask and more generally by the mask as a whole. However, the communication of subjects between them is necessary to enable them to position themselves against each other and possibly to help in case of accident.

  As explained above, multiple devices have been proposed to allow communication between subjects wearing helmets and / or masks. The schematic figures 2A and 2B show means used in the prior art.

  In Figure 2A, there is shown schematically the source of sound vibrations S, namely the mouth. The simplest way to transmit these sound vibrations is to capture them by means of a microphone R, that is to say to receive the vibrations in R and to transform these vibrations into an electrical signal by means of a transducer, then transmit the signal to an amplifier, then to a receiver and finally to a listener. The transducer T is in the microphone R. Such a system works well in the case shown in FIG. 2A, that is to say in the case where the source of sound vibrations is in the same space as the reception R, c that is, the source of acoustic vibrations is not separated from the transducer by a partition, the transmission of acoustic vibrations being in the air. This system is commonly used for transmission from one subject to another wearing a helmet on which the receiver microphone R is supported via a "gooseneck" 8 fixed to the side of the helmet. Several disadvantages arise for such a system. A first disadvantage is that the transducer is poorly protected from shocks and the gooseneck can bend in different directions and move more or less away from the subject's mouth. Another disadvantage, major this one, is that if one wishes to use this device with a mask, the gooseneck can be attached to the outside of the mask for reasons of space and comfort. The transmission of acoustic vibrations is thus prevented by the wall of the mask and in particular by the visor of the mask. The link is bad.

  We have therefore tried to remedy this disadvantage by placing an osteomicrophone at the top of the skull of a subject. Such a device makes it possible to pick up sounds emitted by the cranial box in S with the aid of the osteomicrophone R placed substantially at the emission point S of the sounds. A major disadvantage of this device is that it requires complicated fixing systems of the microphone R so that it remains perfectly in contact with the cranial bones. These fastening systems are expensive and impractical. In addition, they require a precise adjustment of the microphone on the skull, this adjustment requiring time. However, the time factor is essential, especially in the case of firefighters who must respond quickly to the scene of a disaster (fires, chemical attacks, biological, etc.) and must dress and protect themselves as quickly as possible. In addition, the fastening systems of the osteomicrophones are more or less reliable and they can nevertheless move relative to the skull during interventions. In case of displacement of the osteomicrophone, the contact being hurt with the cranial bones, the sound transmission will be diminished, even interrupted.

  The device according to the present invention solves the problems described in this patent application.

  As seen in FIG. 2C, a microphone R is placed in the vicinity of the source S, outside the mask 1. As seen in more detail in FIG. 3, the microphone comprises an acoustic vibration transducer 10 , receiving means 11 of said transducer 10, said receiving means 11 being spaced from said transducer 10, and resilient means 12 placed between said receiving means 11 and said transducer 10. The receiving means are for example a housing whose bottom is only shown in Figure 3. The transducer 10 is embedded in a flexible and resilient material 14 as a rubbery material. The transducer 10 coated with the rubbery material 14 is placed on a support 13 which is placed between the source S of acoustic vibrations and the transducer 10. Elastic means 12, for example a spring, elastically plate said transducer 10 on said support 13. The flexible and elastic rubber coating is pressed by the spring 12 against the wall of the support 13 and matches the shape of the support 13. This support is indeed a mask visor that can be curved. The coating 14 thus makes it possible to obtain a large contact surface between the support 13 and the coating deformed by the pressure of the spring 12. The sounds coming from the source S are therefore better transmitted to the transducer 10. The device according to the invention The invention solves the adaptation of the rigid housing which contains the transducer and the spring 12 on a curved mask visor. The contact surface between the transducer and the support is increased by the presence of the coating and the transmission of sound in the elastomer is greater than if the rigid transducer is directly in contact with the curved support.

  The transducer 10 coated with the flexible and elastic material 14 and the spring 12 are received in a housing 11 whose bottom is spaced from the transducer 10. More preferably, this transducer 10 is remote from the bottom of the housing 11. The transducer 10 is coated a flexible and deformable material 14 which allows a greater contact area between the transducer 10 and the curved support 13. As seen in Figure 3, the transducer 10 is placed outside the visor 3 of the mask , that is to say that the support 13 is disposed between the source S of acoustic waves and the transducer 10. When the source S emits acoustic waves, they strike the support 13, as represented by arrow F in Figure 3, and the support 13 vibrates. The transducer which is pressed against the support 13 also vibrates due to its elastic plating against the support 13 by means of the spring or springs 12. Preferably, the transducer 10 is for example a vibration transducer manufactured by Knowles Electronics Inc., model BU-1771, BU-3173 or BU-3135.

  The housing 11 may be of any shape (parallelepipedal, cylindrical) but has an opening on one of its sides and receiving said transducer 10, the flexible and elastic coating 14 and the spring 12, this spring being compressed to press the flexible coating 14 on the curved support so that the transmission of acoustic waves from the source S to the transducer.

  The housing is attached to the outside of the helmet or mask on a rigid part thereof, such as the ring (tower) 15 of the visor.

  The attachment is such that the spring is compressed to allow the compression of the coating 14 on the curved support 13.

  However, the positioning of the spring 12 and its compression may be more or less easy to achieve, so according to another embodiment, the fastening means of the housing 11 comprising the transducer 10 coated with the coating 14 are a quick fastening system (Not shown) on a rigid part of the mask such as the ring 15, such as a clip system. This embodiment eliminates the spring 12 while compressing the flexible coating 14 on the visor 13 of the mask.

  The microphone device is designed to withstand water, dust (according to ISO IP68), gases (eg methane), explosive atmosphere (according to ATEX).

Claims (10)

  1. Microphone device characterized in that it comprises a transducer (10) of acoustic vibrations, a coating (14) of said transducer (10) of flexible material, means (12) pressing said transducer (10) and its coating (14). ) on a support (13) and compressing the flexible material of said coating (14), receiving means (11) of said transducer (10) provided with its coating (14), holding means on a support (13) of said transducer (10) provided with its coating (14), said receiving means (11) and said plating means (12); said support (13) being placed between the source S of acoustic vibrations and said transducer (10) coated and remote from said source S. 2. Microphone device according to claim 1, characterized in that said means (12) pressing said transducer and its coating on the support (13) are one or springs placed between said receiving means (11) and said coating (14). .   3. Microphone device according to claim 1, characterized in that said means (12) plating said transducer and its coating on the support are a said holding means constituted by a clipping system on a rigid part of the mask, for example the rod .   4. Microphone device according to claim 1, characterized in that said vibration transducer (10) is placed between said support (13) and said elastic means (12).   5. Microphone device according to any one of the preceding claims, characterized in that said support (13) is placed in front of the mouth of a user and distant from it.   6. Microphone device according to any one of the preceding claims, characterized in that said support (13) is a mask visor.   7. Microphone device according to any one of the preceding claims, characterized in that said support is a helmet visor, said visor being optionally liftable.   8. Mask microphone device according to any one of the preceding claims, characterized in that said microphone device is designed to withstand water, dust (according to ISO IP68), gases (for example, methane ), in an explosive atmosphere (according to the ATEX standard).   Mask microphone device according to one of the preceding claims, characterized in that said microphone device is connected to an amplifier device and then to a transmitter system.   10. Helmet or protective mask provided with the device according to any one of the preceding claims.