DE112006000463B4 - Waterproof hearing aid - Google Patents

Abstract

A waterproof hearing aid having a first waterproof film (16) extending expansively at the sound inlet (5) of a microphone (4) and a second waterproof film (19) expansively provided at the sound outlet (12) of an earphone (11) characterized by first ventilation means (27) having a communication connection between a microphone chamber (18) formed by the first waterproof film (16) and the microphone (4) and a hearing aid housing chamber (22) passing through a hearing aid housing (3) is formed forms; second ventilation means (28) forming a communication connection between an earphone chamber (21) formed by the second waterproof film (19) and the earphone (11) and the hearing aid housing chamber (22); and a third ventilation device (24) forming a communication connection between the hearing aid housing chamber (22) and the outside, and a porous film provided in the third ventilation device (24).

Description

Technical area

The present invention relates to a waterproof hearing aid in which a waterproof structure is provided at the sound inlet of a microphone, at the sound outlet of an earphone and at other locations.

State of the art

For a hearing aid wearer, it is desirable for a hearing aid to be worn in all circumstances. For example, in the case where the wearer perspires as a result of an appropriate amount of exercise of a physical or mental exercise, in the case where the wearer takes a bath in an unused place, such as a sports center, or in others In the event of fall, it is desired that the wearer does not decrease his / her hearing aid due to a need to obtain sufficient information about his / her acoustic sense. However, in such circumstances, the hearing aid wearer / hearing aid wearer is currently wearing or wearing his / her hearing aid while he / she is worried about whether the hearing aid will fail due to the ingress of sweat or water.

In such a situation, as a waterproof structure for a hearing aid type hearing aid, there has been known a structure in which a waterproof film holding member holding a nonporous waterproof film is disposed in front of the sound inlet of a microphone through which the enclosed one State of a microphone chamber, which is formed by the holding member with waterproof film and a microphone housing is improved (see, for example, the patent document 1).

Also, as a waterproof structure for an ear-insertion-type hearing aid, there has been known a structure in which a perforated cover may be attached to a sound-outlet connection part of a hearing aid and a microporous film made of non-tacky polytetrafluoroethylene is provided in the cover, so that sounds can be transmitted in a simple manner and also can be prevented that earwax, moisture, sweat and the like from the ear canal enters the hearing aid (see, for example, the patent document 2).

Further, there has been known a hearing aid in which a protection device using a non-porous membrane formed of a material having a high sound propagation property, such as titanium of 0.01 mm or thinner, is provided instead of the microporous film at a sound inlet opening and a sound outlet opening is (see, for example, Patent Document 3).
Patent Document 1: Japanese Patent No. 2869505
Patent Document 2: European Patent No. 0310866
Patent Document 3: Japanese Patent Application Publication No. 10-126897

Disclosure of the invention

However, in the waterproof structure of the hearing aid described in Patent Documents 1 and 3, the sound hole is covered with the nonporous waterproof film or the non-porous membrane, so that a sound entry path into the microphone (microphone chamber) and a sound exit path from an earphone (earphone chamber) respectively get into a hermetically sealed state. In such an enclosed state, when the air pressure or the temperature on the outside of the hearing aid changes, a difference in the air pressure between the inside and the outside of the enclosed space arises and a pressure on the waterproof caused by this difference in the air pressure acts Film, etc., whereby a high voltage is generated on the waterproof film. As a result, the acoustic impedance of the waterproof film, etc. suddenly increases and the attenuation of a sound pressure caused by the waterproof film, etc., increases, posing a problem in that the sensitivity of a hearing aid greatly lowers ,

Also, when the microporous film is used as described in Patent Document 2, the difference in air pressure does not arise, but the hearing aid of this type has such a disadvantage that the hole in the film easily clogs up with earwax, etc. becomes. Also, the microporous material formed of polytetrafluoroethylene has a higher specific gravity than non-porous polyurethane elastomeric material, and for this microporous material, when the film is made thin, its water-tightness performance lowers, making it difficult to sufficiently lowering the surface density of the film, which poses a problem in that it is difficult to sufficiently lower the acoustic impedance of the film.

This problem also occurs in a DE 196 40 796 A1 described waterproof hearing aid on; having the features of the preamble of claim 1. This hearing aid has no ventilation device.

The acoustic impedance of a film is essentially determined by its acoustic stiffness in a frequency zone that is lower than the first resonant frequency of the film. The acoustic stiffness of a circular film is proportional to the tension of the film and inversely proportional to the fourth power of the film diameter. Particularly, in the case of the ear-insertion type hearing aid, the diameter of a waterproof film is about 2 mm in terms of its design. As the film diameter lowers, the variation in acoustic impedance of the film with respect to the change in film tension suddenly increases. Thus, it is important for the waterproof hearing aid to adjust the air pressure on the inside and outside of the film so that it is in equilibrium to prevent the film tension from changing.

US Pat. No. 6,422,991 B1 relates to a hearing aid with a first and a second ventilation device, but without a further third ventilation device. In this hearing aid, if the diameter of a membrane is large (a few centimeters), the second ventilation device may be useful, but if the diameter of the waterproof film is small (about 2 mm) it is not useful, as described in the previous paragraph ,

The present invention has been made to solve the above-described problems with respect to the related art, and accordingly has an object of providing a waterproof hearing aid that can be worn without worrying about the ingress of sweat or water Even at the time of sweating or bathing to take care of.

In order to solve the above problems, the present invention according to an aspect 1 provides a waterproof hearing aid having a first waterproof film provided expansively at the sound input of a microphone, and a second waterproof film expanding at the sound output of a microphone Earphone is provided. In particular, the waterproof hearing aid has a first ventilation device, which forms a communication connection between a microphone chamber, which is formed by the first waterproof film and the microphone, and a hearing aid housing chamber, which is formed by a hearing aid housing, a second ventilation device, which is a communication link between a Earphone chamber, which is formed by the second waterproof film and the earphone, and the hearing aid housing chamber forms, and a third ventilation device, which forms a communication link between the hearing aid housing chamber and the outside, contains. Furthermore, a porous film is provided in the third ventilation device

The invention according to an aspect 2 is characterized in that, in the waterproof hearing aid described in the aspect 1, the first ventilation means, through a pipe projecting into the hearing aid housing chamber, a ventilation hole provided in the sidewall of a pipe forming part of the microphone chamber forms a permeable porous tube which forms part of the microphone chamber, or a ventilation hole, which is provided in a microphone housing is configured.

The invention according to an aspect 3 is characterized in that, in the waterproof hearing aid described in aspect 1 or 2, the second ventilation means, through a pipe projecting into the hearing aid housing chamber, a ventilation hole provided in the sidewall of a pipe forming part of the pipe Earphone chamber is formed, or a permeable porous tube, which forms part of the earphone chamber is configured.

The invention according to aspect 4 is characterized in that in the waterproof hearing aid described in aspect 1, 2 or 3, the third ventilation means uses a porous polytetrafluoroethylene film which allows gas such as air to pass through and is difficult to let a liquid, such as water, easily pass through.

The invention according to an aspect 5 is characterized in that in the waterproof hearing aid according to aspect 1, 2, 3, 4, the first waterproof film and the second waterproof film can be freely exchanged.

As described above, according to the invention described in aspect 1, the first ventilation device that forms a communication link between the microphone chamber and the hearing aid housing chamber is the second ventilation device that forms a communication link between the earphone chamber and the hearing aid housing chamber, and the third ventilation device provides a communication connection between the hearing aid housing chamber and the outside. Therefore, because the microphone chamber and the earphone chamber are in air communication with the outside, even if the air pressure or the temperature of the outside changes, there is no difference in pressure between the hearing aid housing chamber and the outside, and therefore no high voltage will be applied to the waterproof film so that a problem can be prevented that the acoustic impedance of a waterproof film suddenly increases and the attenuation of a sound pressure due to the waterproof Increased film, whereby the sensitivity of the hearing aid is greatly reduced.

According to the invention described in aspect 2, the microphone chamber and the hearing aid housing chamber can be easily made to communicate with each other in air. Therefore, the balance of air pressures between the microphone chamber and the hearing aid housing chamber is rapidly achieved.

According to the invention described in aspect 3, the earphone chamber and the hearing aid housing chamber can be easily made to communicate with each other in air. Therefore, the balance of air pressures between the earphone chamber and the hearing aid housing chamber is rapidly achieved.

According to the invention described in aspect 4, it is easy to cause the outside and the hearing aid housing chamber to be in air communication with each other without the entry of a liquid, such as water, into the hearing aid housing chamber. Therefore, the balance of air pressures between the outside and the hearing aid housing chamber is rapidly achieved.

According to the invention described in aspect 5, the first waterproof film and the second waterproof film can be easily cleaned or replaced.

Brief description of the drawings

1 Fig. 12 is a perspective view of a waterproof hearing aid according to the present invention;

2 Fig. 13 is a perspective view of a waterproof hearing aid according to the present invention;

3 Fig. 15 is a perspective view showing a state in which a battery lid of a waterproof hearing aid according to the present invention is open;

4 Fig. 10 is a sectional view showing a state in which a waterproof hearing aid according to the present invention is worn;

5 Fig. 10 is a sectional view of a waterproof hearing aid according to the present invention;

6 is a detailed sectional view of a waterproof structure and a first ventilation device of a microphone;

7 Fig. 11 is a detailed sectional view of a waterproof structure and a second ventilation device of an earphone;

8th is a detailed sectional view of a third ventilation device;

9 consists of sectional views showing other embodiments of a first ventilation device, wherein 9 (a) shows a case in which a ventilation hole is provided in a microphone housing, and wherein 9 (b) a case in which a ventilation hole is provided in a rubber pipe;

10 Fig. 10 is a sectional view showing another embodiment of a second ventilation device; and

11 is a sectional view showing another embodiment of a third ventilation device.

Best way to carry out the invention

Embodiments of the present invention will now be described with reference to the accompanying drawings. The 1 and 2 3 are perspective views of a waterproof hearing aid according to the present invention; 3 FIG. 15 is a perspective view showing a state in which a battery lid of the waterproofing hearing aid is open; FIG. 4 Fig. 10 is a sectional view showing a state in which the waterproof hearing aid is worn; 5 is a sectional view of the waterproof hearing aid, 6 is a detailed sectional view of a waterproof structure and a first ventilation device of a microphone, 7 is a detailed sectional view of a waterproof structure and a second ventilation device of an earphone and 8th is a detailed sectional view of a third ventilation device.

As it is in the 1 to 3 1, the waterproof hearing aid according to the present invention is an insertion type hearing aid having a hearing aid housing 3 that through a shell 1 and a front panel 2 that the opening of the shell 1 covering, is formed. The outer shape of the shell 1 is formed so that it to the wall portion of the external auditory canal 10 fits when the hearing aid is worn as it is in 4 is shown.

As it is in 5 is shown is the front panel 2 with a sound inlet 5 a microphone 4 a mounting hole 6 for the microphone 4 that with the sound inlet 5 is in communication connection, a battery compartment accommodation part 9 , of the a battery cover 8th houses a battery 7 holds, and formed like. Likewise, at the very end of the shell 1 a sound outlet 12 an earphone 11 and a mounting hole 13 for the earphone 11 that with the sound outlet 12 is in communication connection formed.

In the case of a customized hearing aid, in which the shell 1 is made by making a model of the ear of the hearing aid wearer, as in 4 shown is a vent hole 14 for ventilation between the outside and the external auditory canal 10 at the time of wearing in the shell 1 intended. However, in the case of a general in-ear type hearing aid for which no model of the hearing aid wearer's ear is made, it is expected that ventilation between the outside and the external auditory canal will be through a gap between the shell and the wall of the ear outer ear canal is maintained, which gap is formed at the time of wearing, so that no ventilation hole is provided.

As it is in 5 shown is a watertight disk 17 Stretching with a waterproof film 16 is provided, in engagement with the sound inlet 5 of the microphone 4 and is a microphone chamber 18 through the waterproof disc 17 and the microphone 4 that in the mounting hole 6 is attached and fixed with adhesive formed. Likewise stands at the sound outlet 12 of the earphone 11 also a waterproof slice 20 Stretching with a waterproof film 19 is engaged and is an earphone chamber 21 through the waterproof disc 20 and the earphone 11 who is in the mounting hole 13 attached and fixed with adhesive is formed. A reference number 15 denotes a signal processing part.

The battery cover 8th is with a through hole 23 formed, which causes the outside and the inside of the hearing aid housing 3 (a hearing aid housing chamber 22 ) are in communication with each other, and a cover 25 expanding with a porous film (a third ventilation device) 24 is provided, is in engagement with the through hole 23 , Furthermore, the battery cover 8th with an O-ring 26 mounted so that, when prompted, the battery cover 8th in a closed state, a waterproof structure is formed so that water, etc., does not enter the hearing aid housing chamber 22 entry.

By using an elastic high molecular weight film formed of, for example, polyurethane elastomer having a thickness of about 0.01 mm as the waterproof film 16 can the acoustic impedance of the waterproof film 16 be lowered to a value related to the acoustic input impedance of the microphone 4 is negligible. Thereby, almost the same feeling for a carrier as in the case where the waterproof film 16 not appropriate to be obtained because of the microphone 4 exerted sound pressure hardly attenuates, even when he walks through the waterproof film.

As it is in 6 is shown, the waterproof film 16 after having a circular shaped frame 16a is connected, inserted into a mold when a cylindrical body 17a of the watertight disk 17 is formed, and is on the cylindrical body 17a fixed by molding. This will make the waterproof disc or the waterproof chip 17 formed, the or from the waterproof film 16 , the frame 16a and the cylindrical body 17a consists. The cylindrical body formed by using an elastic high molecular material 17a will be under pressure in the sound inlet 5 inserted, which has an inside diameter which is slightly smaller than the outside diameter of the cylindrical body 17a is, so the cylindrical body 17a acts as a package to improve the waterproofness of the microphone chamber 18 contribute.

Likewise, as the waterproof film 19 Also, an elastic high molecular weight film, for example, of polyurethane elastomer having a thickness of about 0.01 mm, the same as that of the waterproof film 16 is used, by which the acoustic impedance of the waterproof film 19 can be lowered to a value related to the acoustic output impedance of the earphone 11 is negligible. Thereby, almost the same feeling of a carrier as in the case where the waterproof film is obtained can be obtained 19 not appropriate because of the earphone 11 Sound pressure supplied to the external auditory canal is hardly attenuated even when passing through the watertight film 19 running.

As it is in 7 is shown, the waterproof film 19 after having a circular shaped frame 19a is connected, inserted into a mold when a cylindrical body 20a of the watertight disk 20 is formed, and becomes at the Cylindrical body 20a fixed by molding. This will make the waterproof disc or the waterproof chip 20 formed, the or from the waterproof film 19 , the frame 19a and the cylindrical body 20a consists. The cylindrical body formed by using an elastic high molecular material 20a will be under pressure in the sound outlet 12 with an inside diameter that is slightly smaller than the outside diameter of the cylindrical body 20a is inserted, so that the cylindrical body 20a acts as a package to improve the waterproofness of the earphone chamber 21 contribute.

The waterproof chip 17 and the waterproof chip 20 grab in the front panel 2 or the shell 1 only by taking advantage of elasticity, so that these chips 17 and 20 can be easily removed by using tweezers and thereby replaced with new ones. That means the waterproof film 16 can be freely exchanged because of the waterproof chip 17 can be freely released, and that the waterproof film 19 can be freely exchanged because of the waterproof chip 20 can be freely exchanged.

Likewise, as it is in 6 is shown on the side of the microphone 4 a pipe (a first ventilation device) 27 , which is a communication link of the microphone chamber 18 with the hearing aid housing chamber 22 forms, provided so that the air pressures in the microphone chamber 18 and the hearing aid housing chamber 22 are in balance. When the air pressures in the microphone chamber 18 and the hearing aid housing chamber 22 are not in balance, the microphone chamber 18 an enclosed space, and therefore, a difference in air pressure between the microphone chamber becomes 18 and the outside is generated by a change in temperature or air pressure. Thus, this difference in the air pressure becomes a tension on the waterproof film 16 generates, so that the acoustic impedance of the waterproof film 16 significantly increased, which as a result decreases the sensitivity of the hearing aid.

As it is in 7 shown is on the side of the earphone 11 as well a pipe (a second ventilation device) 28 , which is a communication link of the earphone chamber 21 with the hearing aid housing chamber 22 forms, provided so that the air pressures in the earphone chamber 21 and the hearing aid housing chamber 22 are in balance. When the airlift in the earphone chamber 21 and the hearing aid housing chamber 22 are not in balance, the earphone chamber 21 an enclosed space, and therefore, a change in a temperature or an air pressure becomes a difference in an air pressure between the earphone chamber 21 and the outside generates. Thus, this difference in the air pressure becomes a tension on the waterproof film 19 generates, so that the acoustic impedance of the waterproof film 19 significantly increased, which reduces the sensitivity of a hearing aid as a result.

As it is in 6 shown is the microphone 4 of the type of electret capacitor, in which a box-shaped microphone housing 30 a vibrant movie 31 , a rear electrode electret 32 , an impedance converter 33 and the like. Likewise, the microphone housing 30 through the vibrating film 31 into a front chamber with a vibrating film 34 and a rear chamber with a vibrating film 35 divided up. At a point where the microphone housing 30 the waterproof film 16 is opposite, is a Klangeinlassanschluss 36 , which communicates with the front chamber with vibrating film 34 stands, educated. The one in the front chamber with vibrating film 34 generated sound pressure offset after passing through the waterproof film 16 and the sound inlet port 36 ran, the movie vibrating 31 , the rear electrode electret 32 with a suitable gap provided therebetween so that the acoustic signal is converted into an electrical signal.

In the microphone 4 is a rear electrode electret 32 with one or a plurality of holes (rear electrode holes) 32a designed to obtain satisfactory properties, and in general is the vibrating film 31 even with a small hole (a movie ventilation hole) 31a educated. Therefore, the front chamber communicate with vibrating film 34 and the rear chamber with vibrating film 35 with each other and are the air pressures in the front chamber with vibrating film 34 and the rear chamber with vibrating film 35 in balance.

Likewise, as it is in 7 shown is the earphone 11 an electromagnetic earphone of a balanced armature type in which a box-shaped earphone housing 40 a vibrating plate 41 , a coil 42 , a magnet 43 , an anchor 44 , a vibrating pen 45 and the like. Likewise, the earphone case 40 through the vibrating plate 41 in a front chamber with vibrating plate 46 and a rear chamber with a vibrating plate 47 divided up. At a point where the earphone case 40 the waterproof film 19 is opposite, is a sound outlet 48 , which communicates with the front chamber with vibrating plate 46 stands, educated. The earphone 11 is with adhesive by attaching the outermost end of a rubber tube 50 in one on the earphone case 40 trained sound outlet 49 is inserted in the mounting hole 13 fixed.

The one in the front chamber with vibrating plate 46 by the vibration of the vibrating plate 41 Sound pressure generated runs through the sound outlet 48 , the earphone chamber 21 and the waterproof film 19 and become to the outside (to external auditory canal). The edge part of the vibrating plate 41 is from a flexible high molecular weight film 51 surrounded and the vibrating plate 41 is on the inside wall of the earphone case 40 about the high molecular weight film 51 appropriate. The high molecular weight film 51 is with a small ventilation hole 51a educated. Therefore, the front chamber communicate with vibrating plate 46 and the rear chamber with vibrating plate 47 with each other and are the air pressures in the front chamber with vibrating plate 46 and the rear chamber with vibrating plate 47 in balance.

As it is in 8th is shown, there is the porous film (the third ventilation device) 24 made of a porous polytetrafluoroethylene film with a thickness of 0.3 mm and is through the press-fitted cover 25 , which is made of a water-repellent plastic material, after becoming a step part 23a dropped off, in the through hole 23 fixed in the battery cover 8th is trained. The porous film 24 has a property that allows the film to run through water vapor but does not allow sweat and water to pass through it. Likewise, the porous film has 24 such permeability that the air pressures can equilibrate in about a few seconds when there is a difference in air pressure between the interior of the hearing aid housing chamber 22 and the outside is created.

When the time required for the air pressures to equilibrate is about 10 seconds or longer, the difference in air pressure between the inside of the hearing aid housing chamber disappears 22 and the exterior, which is caused by an abrupt change in air pressure generated in an elevator or the like, not fast. Therefore, the sensitivity of a hearing aid is lowered and therefore the hearing aid wearer feels a difficulty in hearing.

Therefore, it is desirable that the air pressure in the hearing aid housing chamber 22 with the air pressure on the outside in a period of time that is as short as possible, without sacrificing the watertightness.

Likewise, it is desirable that the third ventilation device for ventilation between the hearing aid housing chamber 22 and the outside is provided at a plurality of different locations. This is because, when the third ventilation means is provided at one place only, although normally sufficient permeability is ensured, the balance of air pressures due to clogging of the porous film 24 can be lost with drops of water or the like. If a plurality of the third ventilation means is provided, the possibility is lower that all of the porous films 24 are clogged with water drops, as in the case in which the third ventilation means is provided in one place.

Next, as another embodiment, the first ventilation device as shown in FIG 9 (a) shown is a ventilation hole 55 in the microphone housing 30 instead of the pipe 27 provided, which is a communication link of the microphone chamber 18 with the hearing aid housing chamber 22 forms. This allows the balance of air pressures between the microphone chamber 18 and the hearing aid housing chamber 22 through the movie ventilation hole 31a to be achieved in the vibrant movie 31 is trained.

Likewise, as it can in 9 (b) As shown, the configuration may be such that a cylindrical sound inlet 30a on the microphone housing 30 is formed, a rubber tube 56 to the sound inlet 30a is laid and the rubber tube 56 in the mounting hole 6 of the microphone 4 attached and fixed with an adhesive. In this case, there is a ventilation hole 57 in the sidewall of the rubber tube 56 formed by a laser beam machining, whereby the balance of air pressures between the microphone chamber 18 and the hearing aid housing chamber 22 can be achieved.

Also, by using a pipe made of porous polytetrafluoroethylene resin, etc., instead of the rubber pipe 56 the balance of air pressures between the microphone chamber 18 and the hearing aid housing chamber 22 be achieved without forming the ventilation hole in the side wall of the tube. The ventilation hole for the balance of air pressures between the microphone chamber 18 and the hearing aid housing chamber 22 may be provided anywhere or at a variety of locations.

Next, as another embodiment, the second ventilation device as shown in FIG 10 shown is a ventilation hole 58 by a laser beam machining in the sidewall of the rubber tube 50 trained in the mounting hole 13 attached and fixed with an adhesive, thereby maintaining the balance of air pressures between the earphone chamber 21 and the hearing aid housing chamber 22 can be achieved. Also, by using a pipe made of porous polytetrafluoroethylene resin, etc., instead of the rubber pipe 50 the balance of air pressure between the earphone chamber 21 and the hearing aid housing chamber 22 be achieved without forming the ventilation hole in the side wall of the tube. Furthermore, the ventilation hole for the balance of air pressures between the earphone chamber 21 and the hearing aid housing chamber 22 be provided at any point or in a variety of places.

Next, as another embodiment, the third ventilation device as shown in FIG 11 shown is an opening 60 leading to the hearing aid housing chamber 22 open, in the ventilation hole 14 provided, and this opening 60 is with a porous polytetrafluoroethylene film 61 covered, reducing the balance of air pressure between the hearing aid housing chamber 22 and the outside through the ventilation hole 14 can be achieved. Likewise, by forming the ventilation hole 14 by a pipe made of porous polytetrafluoroethylene resin, etc., the balance of air pressures between the hearing aid housing chamber 22 and the outside can be achieved without forming the ventilation hole in the sidewall of the pipe.

When the ventilation ability between the microphone chamber 18 and the hearing aid housing chamber 22 and the ventilation ability between the earphone chamber 21 and the hearing aid housing chamber 22 are too high and therefore the acoustic impedance in the audio frequency band is too low, the acoustic systems of the microphone chamber interfere 18 , the earphone chamber 21 , the hearing aid housing chamber 22 and the external auditory canal with each other, whereby a problem regarding the hearing aid characteristics can be imposed.

Therefore, these ventilation capabilities are determined so that the equilibrium of air pressures is achieved in a time period as short as a few seconds or shorter and the acoustic impedance is high to such an extent that a change in characteristics as compared with the case is negligible, in which no ventilation device is provided. For the pipe (the first ventilation device) 27 and the pipe (the second ventilation device) 28 , in the 5 are shown, an inside diameter of 0.1 mm and a length of 10 mm were used.

Industrial applicability

According to the present invention, there is provided a waterproof hearing aid that can be worn without worrying about the entry of sweat or water even at the time of sweating or bathing. Therefore, it becomes easy to handle the waterproof hearing aid, so that a demand for the waterproof hearing aid can be lowered.

Claims (5)

Waterproof hearing aid with a first waterproof film ( 16 ), which expands at the sound inlet ( 5 ) of a microphone ( 4 ) and a second waterproof film ( 19 ), which expands at the sound outlet ( 12 ) of an earphone ( 11 ) is provided, characterized by a first ventilation device ( 27 ), which is a communication link between a microphone chamber ( 18 ) through the first waterproof film ( 16 ) and the microphone ( 4 ), and a hearing aid housing chamber ( 22 ) through a hearing aid housing ( 3 ) is formed forms; a second ventilation device ( 28 ), which is a communication link between an earphone chamber ( 21 ) through the second waterproof film ( 19 ) and the earphone ( 11 ), and the hearing aid housing chamber ( 22 ) forms; and a third ventilation device ( 24 ), which establishes a communication connection between the hearing aid housing chamber ( 22 ) and the outside, and a porous film which is in the third ventilation device ( 24 ) is provided. A waterproof hearing aid according to claim 1, wherein the first ventilation device ( 27 ) a tube that enters the hearing aid housing chamber ( 22 ) projecting, a ventilation hole in the side wall of a tube-forming part of the microphone chamber ( 18 ), a permeable porous tube forming part of the microphone chamber ( 18 ), or a ventilation hole formed in a microphone housing ( 30 ) is provided. A waterproof hearing aid according to claim 1 or 2, wherein the second ventilation device ( 28 ) a tube that enters the hearing aid housing chamber ( 22 ) protrudes, a ventilation hole provided in the sidewall of a tube forming part of the earphone chamber ( 21 ) or a permeable porous tube forming part of the earphone chamber ( 21 ) is. A waterproof hearing aid according to claim 1, 2 or 3, wherein the third ventilation device ( 24 ) uses a porous polytetrafluoroethylene film which allows gas such as air to pass therethrough, and it is difficult to easily pass a liquid such as water. A waterproof hearing aid according to claim 1, 2, 3 or 4, wherein said first waterproof film ( 16 ) and the second waterproof film ( 19 ) are interchangeable.

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