KR100282066B1 - Transducer of Middle Ear Implant Hearing Aid - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transducer for a hearing aid implanted in the middle ear, comprising a coil generating a magnetic flux by an input signal, a ferromagnetic member for increasing the magnetic flux of the coil, a permanent magnet vibrating with the increased magnetic flux by the ferromagnetic member, and a ferromagnetic material. A first flexible member interposed between the member and the permanent magnet to maintain a constant distance between the ferromagnetic member and the permanent magnet, and a case accommodating the coil, the ferromagnetic member, the permanent magnet and the first flexible member. . Such a transducer can be easily implanted into the middle ear at the same time as it effectively converts the voice current for external sound into vibration with mechanical sound pressure.

Description

Transducer of Middle Ear Implant Hearing Aid

The present invention relates to a transducer of a hearing aid, and more particularly to a transducer of a middle ear implantable hearing aid implanted permanently in the middle ear.

Hearing aids include an external mounting type installed behind the ear canal and the auricle, a bone conduction type that vibrates the temporal bone by converting sound into vibrations, an inner ear implantation type inserted into the inner ear through surgery, and a middle ear transplantation type that is inserted into the middle ear.

Among these various existing hearing aids, middle ear implant type hearing aids are widely used.

FIG. 1 is a view illustrating a state in which a transducer of a conventional middle ear implantable hearing aid is implanted in the stator bone, and FIG. 2 is a schematic perspective view of the transducer of FIG. 1. Hearing aids as shown is composed of an extracorporeal device (10) mounted on the auricle part, and a body (20) implanted in the outer and middle ear. The external device 10 includes a microphone 11, an amplifier 12, a battery 13, and an external device connection coil 14. The body 20 is a body circuit (not shown) located adjacent to the external device connecting coil 14, and an incus 9 or stirrup of the connecting coil 24 and the three osseous bones (scavenging bone) of the middle ear. a transducer 25 implanted in a stapes 8.

As shown in FIG. 2, the transducer 25 includes a coil 26 installed around the middle ear and a permanent magnet 27 installed on the anvil bone 9 or the stirrup bone 8. The coil 26 is composed of a support 26a fixed to the bone around the middle ear, and a coil 26b supported by the support 26a in a state facing the permanent magnet 27. The coil 26b generates magnetic flux when the sound signal is transmitted from the internal connection coil 24 in an electrical form, and the magnetic flux vibrates the permanent magnet 27 that is implanted in contact with the stirrup bone 8.

In the hearing aid having such a structure, the microphone 11 and the amplifier 12 of the external device 10 input and amplify an external sound signal, and the amplified sound signal is converted into an electric signal and the external device connection coil 14 Is sent. The electrical sound signal is transmitted to the internal body connecting coil 24 in the form of electromagnetic waves, and the body connecting coil 24 transmits the sound signal to the transducer 25. As a result, the transducer 25 vibrates the stator bone 8, and through this process, a person can hear external sounds.

However, in the transducer having the above structure, the magnetic flux generated by the input electric signal is small because the coil 26b for generating the magnetic flux is an air core coil without an iron core for increasing the magnetic flux. Therefore, the permanent magnet 27 cannot be vibrated greatly.

In order to increase the magnetic flux, when the iron core is inserted into the coil 26b, the iron core and the permanent magnet 27 are continuously drawn to each other even when there is no signal input to the coil 26b. Force is applied. The scavenging bone is very delicate and can be damaged by the force generated between the permanent magnet and the iron core, and this force can cause deformation in the sound transmission path of the inner ear opening.

In addition, it is very important to keep the distance between the coil 26 and the permanent magnet 27 at all times, and when the fluid enters between the coil 26 and the permanent magnet 27, dryness or debris enters the gap between them. This can cause a big problem with the correct vibration.

On the other hand, in order to implant the coil 26, the bone of the human body of the middle ear part should be scraped off and parts such as the support 26a should be fixed. Therefore, there is a fear of causing deformation in the bone of the middle ear.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a transducer of a middle ear implantable hearing aid that can operate effectively even with a low sound signal and is easy to install.

1 is a view illustrating a state in which a transducer of a conventional middle ear implantable hearing aid is implanted into the stator bone,

2 is a schematic perspective view of the transducer of FIG. 1, FIG.

3 is a view showing a state in which the first embodiment of the middle ear implantable transducer of the present invention is attached to the stator bone,

4 is an exploded perspective view of the transducer of FIG. 3, FIG.

5 is an assembled perspective view of the transducer of FIG. 4;

6 is an exploded perspective view of a second embodiment of the middle ear implantable transducer of the present invention;

7 is an assembled perspective view of the transducer of FIG. 6, FIG.

8 is a view showing a state in which the first embodiment or the second embodiment of the transducer of the present invention is attached to the ankle bone,

9 is a view showing a state between the hammer bone and the stirrup of the first embodiment or the second embodiment of the transducer of the present invention,

<Explanation of symbols for main parts of the drawings>

8 ... stirrups 9 ... anvils

10 ... in vitro 11 ... microphone

12 ... amplifier 13 ... battery

14 ... In Vitro Connection Coil 24 ... In Vitro Connection Coil

120, 220 ... transducers 121, 221 ... coils

122, 222 ... ferromagnetic members 123, 223 ... permanent magnet

124 ... first flexible member 125, 225 ... case

125a ... pipe part 125b, 125c ... first and second cover

126 ... second flexible member 224 ... flexible member

225 ... first case 225a ... first part

225b ... first cover 226 ... second case

226a ... second tube 226b ... second cover

200, 300 ... sieve

In order to achieve the above object, the first embodiment of the middle ear implantable transducer of the present invention, the coil 121 for generating a magnetic flux by the transdue input signal; Ferromagnetic member 122 for increasing the magnetic flux of the coil 221; Permanent magnets 123 vibrating at an increased magnetic flux by the ferromagnetic member 122; A first flexible member 124 interposed between the ferromagnetic member 122 and the permanent magnet 123 to maintain a constant distance between the ferromagnetic member and the permanent magnet; A case 125 for accommodating the coil 121, the ferromagnetic member 122, the permanent magnet 123, and the first flexible member 124 may be provided.

On the opposite side of the first flexible member 124 around the permanent magnet 123, a second flexible member 126 for maintaining a constant distance between the permanent magnet 123 and one end of the case is further included. Is installed. The ferromagnetic member 122 is composed of a core 122a inserted into the coil 121 and a core head 122b integrated with the core 122a and having a diameter substantially the same as that of the permanent magnet 123. In addition, the case 125 is preferably made of titanium having biocompatibility.

In order to achieve the above object, the first embodiment of the middle ear implantable transducer of the present invention, the coil 221 for generating a magnetic flux by the input signal; Ferromagnetic member 222 to increase the magnetic flux of the coil 221; Permanent magnets 223 vibrating at an increased magnetic flux by the ferromagnetic member 222; A first case 225 accommodating the coil 221 and the ferromagnetic member 222; The second case 226b for accommodating the permanent magnet 223: interposed between the ferromagnetic member 222 and the permanent magnet 223 between the first case 225 and the second case 226 It is characterized in that it comprises a; flexible member 224 to maintain a constant distance.

The ferromagnetic member 222 is composed of a core 222a inserted into the coil 221 and a core head 222b integrated with the core 222a and having a diameter substantially the same as that of the permanent magnet 223. . The first case 225 or the second case 226 is preferably made of a titanium material having biocompatibility.

Hereinafter, embodiments of the transducer of the middle ear implantable hearing aid according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a view showing a state in which the first embodiment of the middle ear implantable transducer of the present invention is attached to the stator bone, Figure 4 is an exploded perspective view of the transducer of Figure 3, Figure 5 is an assembly of the transducer of Figure 4 Perspective view. Here, the same reference numerals as in FIG. 1 denote the same members having the same function.

Hearing aids as shown is composed of an extracorporeal device 10 mounted on the auricle wheel part, and a body 200 implanted in the outer and middle ear. The external device 10 is composed of a microphone 11, an amplifier 12, a battery 13 and the external device connecting coil 14, the body 200 is located adjacent to the external device connecting coil 14 It consists of an intra body connection coil 24 and a transducer 120 attached to the three osseous bones (cleaning bones) of the middle ear, for example, the stirrup bone 8.

As illustrated in FIG. 4, the transducer 120 employed in the hearing aid includes the coil 121 generating magnetic flux by an input electrical signal and the ferromagnetic member 122 increasing the magnetic flux of the coil 121. And a permanent magnet 123 vibrating by the magnetic flux generated by the coil 121 and the ferromagnetic member 122. The ferromagnetic material is preferably a soft iron core having a high permeability and a low residual magnetic flux density.

A first flexible member 124 is disposed between the ferromagnetic member 122 and the permanent magnet 123 to maintain a constant distance between the ferromagnetic member 122 and the permanent magnet 123 while maintaining effective distance.

The coil 121, the ferromagnetic member 122, the permanent magnet 123, and the first flexible member 124 are accommodated in the case 125. At this time, on the opposite side of the first flexible member 124 around the permanent magnet 123 to maintain the distance between the permanent magnet 123 and the second cover (125c) to be described later ( 126) is further interposed. Here, the first flexible member 124 or the second flexible member 126 is preferably made of a flexible material such as silicone having good elasticity and excellent biocompatibility.

The coil 121 is connected to the body connection coil 24 and has a concentric shape. At this time, the wire 121a connecting the internal connection coil 24 and the coil 121 is also coated with a polymer material such as polyurethane having excellent biocompatibility.

The ferromagnetic member 122 that increases the magnetic flux generated by the coil 121 is a core head 122a inserted into the coil 121 and a core head integrated with the core 122a and having a diameter substantially the same as that of the permanent magnet 123. And 122b.

The case 125 includes a cylindrical tube portion 125a having a through hole formed therein, a first cover 125b for sealing the tube portion 125a on the coil 121 side, and a tube portion 125a on the permanent magnet 123 side. ) Is composed of a second cover 125c for sealing. The coil 121, the ferromagnetic member 122, the permanent magnet 123, and the first and second flexible members 124 and 126 are assembled as shown in FIG. 5 and stored in the pipe part 125a. When both sides of the 125a are covered with the first and second covers 125b and 125c and sealed, the above components are completely blocked from the outside. The case 125 is preferably made of titanium having excellent biocompatibility.

In this embodiment, the length of the coil 121 is 0.8mm, the thickness of the core 122a in the ferromagnetic member is 0.8mm. The thickness of the core head 122b is 0.2 mm, the thickness of the first and second flexible members 124 and 126 is 0.3 mm, the thickness of the permanent magnet 123 is 0.6 mm, and the length of the pipe 125a is 2.2. The first and second lids 125b and 125c are 0.2 mm thick, respectively. When all the above components are accommodated in the tube part, the total length of the transducer 120 is only 2.6 mm, and the diameter is only 1.6 mm. The coil 121, the ferromagnetic member 122, the first and second flexible members 124 and 126, the permanent magnet 123, and the like are accommodated in the pipe part 125a in the first and second covers ( Since it is sealed by 125b) and 125c, air or foreign matter does not enter the case 125. in this condition. One end of the transducer 120 is attached to the stator bone 8 using a ceramic adhesive mainly used in dentistry, and the second cover 125c side of the case 125 is preferably attached. Such a transducer 120 may be attached to the anvil bone 9 of the middle ear, as shown in FIG. 8 or 9, or may be attached between the hammer bone 7 and the stirrup bone 8.

In the hearing aid having such a structure, the microphone 11 and the amplifier 12 of the external device 10 input and amplify an external sound signal, and the amplified sound signal is transmitted to the external device connection coil 14. . The electrical sound signal is transmitted to the transducer 120 via the internal connection coil 24. The electrical sound signal transmitted to the transducer 120 is converted into a magnetic flux that is changed by the coil 121. The magnetic flux is enlarged by the ferromagnetic member 122, and the permanent magnet 123 and the coil 121 vibrate in response to this magnetic flux in response to the magnetic flux. At this time, since the first flexible member 124 is interposed between the ferromagnetic member 122 and the permanent magnet 123, their spacing is kept constant. The vibration generated in this way is transmitted to the entire case (125). Since the vibration of the case 125 is transmitted to the stirrup bone 8 or the anvil bone 9 or the hammer bone 7 and the stirrup bone 8 as a result, the sound of the outside is amplified to generate the effect of hearing. Applicant experimented through the transducer as described above, it was possible to obtain the frequency of the dynamic range from tens of Hz to 6Khz.

Next, a second embodiment of the transducer of the middle ear implantable hearing aid of the present invention will be described. 6 is an exploded perspective view of a second embodiment of the middle ear implantable transducer of the present invention, and FIG. 7 is an assembled perspective view of the transducer of FIG. 6. 6 to 9, the hearing aid is composed of an extracorporeal device 10 mounted on the auricle part, and a body 300 implanted in the outer and middle ear. Since the external body is the same as that described in the first embodiment, detailed description thereof will be omitted.

The internal body 300 includes an internal body connection coil 24 positioned adjacent to the external body connection coil 14 and three osseous bones (cleaning bones) of the middle ear, for example, the stirrup bone 8, the anvil bone 9, or the hammer. It consists of a transducer 220 attached between the bone 7 and the stirrup 8.

The transducer 220 employed in the hearing aid as described above includes a coil 221 generating magnetic flux by an input electrical signal, a ferromagnetic member 222 increasing magnetic flux of the coil 221, and coils 221 to. It has a permanent magnet 223 vibrating by the magnetic flux generated by the ferromagnetic member 222. The ferromagnetic material is preferably a soft iron core having a high permeability and a low residual magnetic flux density.

A flexible member 224 is interposed between the ferromagnetic member 222 and the permanent magnet 223 to maintain a constant distance between the ferromagnetic member 222 and the permanent magnet 223. The first case 225 for accommodating the coil 221 and the ferromagnetic member 222 is positioned on one side of the flexible member 224, and the second case 226 for accommodating the permanent magnet 223 on the other side thereof. Is located.

The coil 221 is connected to the body connection coil 24 and has a concentric shape. At this time, the wire 221a connecting the internal connection coil 24 and the coil 221 is also coated with a high molecular material such as polyurethane having excellent biocompatibility.

The ferromagnetic member 222 that increases the magnetic flux generated by the coil 221 is a core 222a inserted into the coil 221 and a core head integrated with the core 222a and having a diameter substantially the same as that of the permanent magnet 223. 222b.

The first case 225 has a cylindrical first tube portion 225a having a through hole formed therein, and a first cover 225b for sealing an end portion of the first tube portion 225a in a state in which the coil 221 is accommodated. It consists of. The second case 226 is composed of a second cylindrical tube portion 226b having a through hole formed therein, and a second cover 226a for sealing an end portion in a state in which the permanent magnet 223 is accommodated. The first and second cases 225 and 226 are preferably made of titanium having excellent biocompatibility.

The flexible member 224 maintains a constant distance between the first case 225 accommodating the coil 221 and the ferromagnetic member 222 and the second case 226 accommodating the permanent magnet 223. Meanwhile, the first case 225 and the second case 226 may vibrate effectively each other. Since the flexible member 224 may be exposed to the outside and come into contact with the human body, the flexible member 224 may be made of a silicone material having excellent biocompatibility and excellent elasticity.

Since the musk of each member described above is similar to that described in the first embodiment, detailed description thereof will be omitted.

Since the coil 221 and the ferromagnetic member 222 are sealed by the first cover 225b in a state in which the coil 221 and the ferromagnetic member 222 are accommodated in the first pipe part 225a, air or foreign matter does not flow into the first case 225. Since the magnet 223 is sealed with the second cover 226b in a state in which the magnet 223 is accommodated inside the second pipe part 226a, the permanent magnet 223 is not exposed to the outside.

in this condition. The second case 226 containing the permanent magnet 223 is attached to the stirrup bone 8 as shown in FIG. 3 using a ceramic adhesive mainly used in dentistry, or the anvil bone 9 as shown in FIG. 8. ), Or between the hammerbone 7 and the stirrup 8, as shown in FIG. 9.

In the hearing aid having such a structure, the microphone 11 and the amplifier 12 of the external device 10 input and amplify an external sound signal, and the amplified sound signal is transmitted to the external device connection coil 14. . The electrical sound signal is transmitted to the transducer 220 via the internal connection coil 24. The electrical sound signal transmitted to the transducer 220 is converted into a magnetic flux that is changed by the coil 221. The magnetic flux is increased by the ferromagnetic member 222, and interlocked with the magnetic flux, the first case 225 in which the coil 221 and the ferromagnetic member 222 are accommodated, and the second case in which the permanent magnet 223 is accommodated. 226 vibrates in an interactive reaction. The vibration generated in this way is transmitted to the stirrup bone (8), hammer bone (7) or anvil bone (9), as a result of the external sound is amplified to produce the effect of hearing.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom.

As described above, the transducer of the middle ear implant hearing aid of the present invention can increase the magnetic flux generated in the coil by using a ferromagnetic member, thereby increasing the degree of vibration of the entire case. Therefore, hearing aid efficiency can be greatly improved.

In addition, since the permanent magnet and the ferromagnetic member are housed inside the case, the load is not applied to the cleaning bone even when a force that is pulled between the permanent magnet and the ferromagnetic member does not cause a deformation in the sound transmission path of the inner ear opening. Do not.

In addition, since the distance between the coil and the permanent magnet is always kept constant by the first flexible member, the degree of hearing is kept constant even after a long time.

In addition, since the transducer is implanted into the middle ear by the adhesive, there is no need to scrape the bone of the human body of the middle ear part or fix parts such as the support 26a (Fig. 2) as in the prior art. Therefore, there is an effect that can facilitate the operation.

Claims (7)

A coil 121 generating magnetic flux by an input signal; Ferromagnetic member 122 for increasing the magnetic flux of the coil 221; Permanent magnets 123 vibrating at an increased magnetic flux by the ferromagnetic member 122; A first flexible member 124 interposed between the ferromagnetic member 122 and the permanent magnet 123 to maintain a constant distance between the ferromagnetic member and the permanent magnet; And a case (125) for accommodating the coil (121), the ferromagnetic member (122), the permanent magnet (123), and the first flexible member (124). The method of claim 1, On the opposite side of the first flexible member 124 around the permanent magnet 123, a second flexible member 126 for maintaining a constant distance between the permanent magnet 123 and one end of the case is further included. Transducer of the middle ear implant hearing aid, characterized in that it is installed. The method of claim 1, The ferromagnetic member 122 is composed of a core 122a inserted into the coil 121 and a core head 122b integrated with the core 122a and having a diameter substantially the same as that of the permanent magnet 123. Transducer of middle ear implantable hearing aid. The transducer of claim 1, wherein the case (125) is made of a biocompatible titanium material. A coil 221 generating magnetic flux by an input signal; Ferromagnetic member 222 to increase the magnetic flux of the coil 221; Permanent magnets 223 vibrating at an increased magnetic flux by the ferromagnetic member 222; A first case 225 accommodating the coil 221 and the ferromagnetic member 222; Second case 226b for receiving the permanent magnet 223: A flexible member 224 interposed between the ferromagnetic member 222 and the permanent magnet 223 to maintain a constant distance between the first case 225 and the second case 226. Transducer of middle ear implantable hearing aid, characterized in that. The method of claim 5, The ferromagnetic member 222 is composed of a core 222a inserted into the coil 221 and a core head 222b integrated with the core 222a and having a diameter substantially the same as that of the permanent magnet 223. A transducer for a middle ear implantable hearing aid. 6. The transducer of claim 5, wherein the first case (225) or the second case (226) is made of a biocompatible titanium material.