JP6230147B2 - Dynamic microphone - Google Patents

Description

  The present invention relates to a dynamic microphone, and more particularly to a dynamic microphone that can cancel vibration noise generated by the inertial force of a voice coil.

Conventionally, dynamic microphones (electrodynamic microphones) have a defect in that since the inertial mass of the voice coil is large, vibrations transmitted to the microphone case are largely picked up and disturbance noise is large. In particular, in the case of a primary sound pressure gradient type microphone, since the control method of the bi-directional component is mass control, the resonance frequency of the diaphragm is designed to be lower than the main sound collection band, and a large vibration occurs at the resonance frequency of the diaphragm. Noise is generated.
To deal with such problems, Patent Document 1 discloses a method (microphone structure) in which a vibration pickup is provided in a dynamic microphone and the vibration noise of the microphone unit is canceled by the output.

The structure of the microphone disclosed in Patent Document 1 is shown in the sectional view of FIG. In FIG. 3, a microphone 50 has a microphone unit 53 arranged coaxially in a cylindrical microphone case 51 via a support member 52 such as rubber.
In front of the microphone unit 53, an electrodynamic microphone constituting body 60 including a magnet 54, a yoke 55, a diaphragm 57 with a voice coil 56, and the like is disposed.
In addition, a cancel coil 61 for canceling disturbance vibration is wound around the base of the electrodynamic microphone constituting body 60, and a magnet 62 is fixed to the inner surface of the case 51 so as to face the coil 61, thereby vibrating. A detection device 65 is configured.

  The voice coil 56 and the cancel coil 61 are connected so as to be in opposite phase connection with respect to external vibration, and the primary of the microphone transformer 66 passes through a lead wire (not shown) from this connection portion. Connected to the side. The secondary side of the microphone transformer 66 is connected to a terminal pin 68 provided on an insulating seat 67 at the bottom of the case 51.

According to the microphone 50 configured as described above, when a sound wave reaches the diaphragm 57, the voice coil 56 vibrates and can be used normally as a microphone.
When unnecessary vibration is applied to the microphone case 51 from the outside, the microphone unit 52 vibrates relative to the case 51 against the elasticity of the elastic support member 52 due to its inertia. For this reason, an electromotive force is generated in the cancel coil 61 due to disturbance vibration of the cancel coil 61 in the magnetic field of the magnet 62.
On the other hand, an electromotive force due to external vibration is also generated in the voice coil 56 of the diaphragm 57. Each coil 56, Since 61 are connected to each other, only noise components due to unnecessary external vibrations can be canceled out without impairing the acoustic characteristics of the microphone.

JP 55-124395 A

  However, in the microphone structure disclosed in Patent Document 1, the magnet 62 facing the cancel coil 61 is in direct contact with the microphone case 51, and unnecessary vibration is applied to the microphone case 51 from the outside. The magnet 62 also vibrates. Therefore, in order to accurately pick up only the vibration of the voice coil 56 due to external vibration, the microphone unit 52 is mounted in the case 51 via the elastic support member 52, and then the output of the vibration detection device 65 is adjusted to adjust the microphone. There is a problem that it is necessary to cancel the vibration noise of the unit 52, and the work related to the manufacturing is complicated.

  The present invention has been made paying attention to the above-described points, and in a dynamic microphone, vibration noise generated by the inertial force of a voice coil can be canceled, and the manufacturing work can be made easier than before. An object of the present invention is to provide a dynamic microphone.

In order to solve the above-described problems, a dynamic microphone according to the present invention is a dynamic microphone including a microphone unit that converts sound waves into electric signals based on vibrations of a diaphragm and a voice coil caused by incoming sound waves, and the microphone unit A unit supporting member that supports the unit supporting member, a cylindrical weight member that supports the unit supporting member via an elastic member, and a voice coil of the microphone unit. as well as have the cancel coils connected as opposite phases connected to each other with respect to external vibration, a magnet and a corresponding said cancel coils, so as to face each other and the weight member side and the unit support member side Vibration pickup means disposed on the micro A microphone case that houses the unit unit, the unit support member, the weight member, and the vibration pickup means, and the microphone case supports the weight member housed in the internal space via an elastic member. It has the feature in being.

According to such a configuration, a vibration speed difference between the weight member and the unit support member that supports the microphone unit can be picked up and vibration noise in the microphone unit can be offset.
Further, according to this configuration, the microphone unit, the elastic member, and the vibration pickup means are all included in the subassembly excluding the microphone case. That is, it is possible to construct a configuration that cancels vibration noise before incorporating such a subassembly into the microphone case, and adjusts the output of the vibration pickup means after mounting the microphone unit in the case as in the past. There is no need to do. Therefore, the manufacturing work can be made easier than the conventional microphone that cancels the vibration noise by using the vibration pickup means.
In addition, since the microphone case supports the weight member housed in the internal space via an elastic member, vibration transmitted from the microphone case to the weight member can be suppressed, and vibration pickup means The output can be maintained with high accuracy.

  ADVANTAGE OF THE INVENTION According to this invention, in the dynamic microphone, the vibration noise which generate | occur | produces with the inertial force of a voice coil can be canceled, and the operation | work which concerns on manufacture can be made easier than before.

FIG. 1 is a cross-sectional view of a dynamic microphone according to the present invention. FIG. 2 is a cross-sectional view showing a state of the subassembly in which the microphone case is removed from the dynamic microphone of FIG. FIG. 3 is a cross-sectional view of a conventional dynamic microphone.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a cross-sectional view of a dynamic microphone according to the present invention. FIG. 2 is a cross-sectional view showing a state of the subassembly in which the microphone case is removed from the dynamic microphone of FIG.

A dynamic microphone 1 shown in FIG. 1 includes, for example, a die-cast microphone case 2 and a subassembly 1A accommodated in the microphone case 2.
As shown in FIG. 2, the subassembly 1 </ b> A is provided on the lower end side of the microphone unit 3, a substantially cylindrical cavity sleeve 4 (unit support member) connected to the lower side of the microphone unit 3, and the cavity sleeve 4. A vibration pickup means 5 and a substantially cylindrical weight member 16 disposed so as to surround the cavity sleeve 4 are provided.

The microphone unit 3 includes an annular yoke 9, a magnet 8 disposed in the center thereof, a voice coil 6 disposed in a gap between the yoke 9 and the magnet 8, and a vibration to which the voice coil 6 is attached. This is a configuration of a known dynamic (electrodynamic) microphone having a plate 7.
The cavity sleeve 4 is preferably made of die cast or synthetic resin, and the inside of the cavity is used as a part of the acoustic circuit of the microphone unit 3.
The microphone unit 3 is supported by the cavity sleeve 4 by inserting the rear end portion 3 a into the front end opening 4 a of the cavity sleeve 4.

Further, a front shock mount member 11 (elastic member) made of an annular body of a rubber elastic material is attached to the outer peripheral surface on the distal end side of the cavity sleeve 4. The front shock mount member 11 includes an inner locking portion 11a that is locked to the outer peripheral surface of the cavity sleeve 4 and a substantially cylindrical support member 2e that is a component of the microphone case 2 and is erected in the case 2 (see FIG. 1) and an outer locking portion 11b that locks to the inner peripheral surface, and a curved leaf spring-like spring portion 11c that connects the inner locking portion 11a and the outer locking portion 11b.
An insertion hole 16a is formed in the upper part of the weight member 16 surrounding the cavity sleeve 4, and an insertion protrusion 11d formed on the outer locking portion 11b of the front shock mount member 11 is inserted into the insertion hole 16a. It has become a state. As a result, the distal end side of the cavity sleeve 4 is supported by the weight member 16 and the support member 2 e in the microphone case 2 via the front shock mount member 11.

A rear shock mount member 12 (elastic member) made of a rubber elastic ring is mounted on the rear end side of the cavity sleeve 4. The rear shock mount member 12 includes an inner locking portion 12 a that is locked to the bottom surface side of the cavity sleeve 4, and an outer locking that is locked to the support member 2 e in the microphone case 2 and the lower end portion of the weight member 16. It comprises a portion 12b and a curved leaf spring-like spring portion 12c that connects the inner locking portion 12a and the outer locking portion 12b.
More specifically, a through hole 4b is formed at the bottom of the cavity sleeve 4, a cylindrical pin holder 13 is fitted into the through hole 4b, and a flange 13a protruding outward is formed at the lower end of the pin holder 13. Has been. The inner locking portion 12a of the rear shock mount member 12 is fitted into a space between the flange portion 13a and the magnet 15 which is a constituent member of the vibration pickup means 5 installed on the bottom surface of the cavity sleeve 4. ing.
Thereby, the rear end side of the cavity sleeve 4 is supported by the weight member 16 and the support member 2 e in the microphone case 2 via the rear shock mount member 12.

  The weight member 16 is made of, for example, die cast and is formed in a cylindrical shape. The front end of the weight member 16 is supported by a front shock mount member 11 that is a rubber elastic body, and the rear shock mount member 12 is a rubber elastic body on the rear end side. It is supported by. That is, the weight member 16 is isolated from the microphone case 2 by a rubber elastic body.

The vibration pickup means 5 includes an annular magnet 15 provided on the bottom surface of the cavity sleeve 4, a cancel coil 17 disposed around the magnet 15 at the lower end of the weight member 16. have.
Although not shown, the voice coil 6 and the cancel coil 17 are connected so as to be connected in opposite phases with respect to external vibration, and vibration noise generated by vibration of the voice coil 6 due to external vibration. Is made to offset.
As described above, since the weight member 16 is isolated from the microphone case 2 by the rubber elastic body, the output of the external vibration detected by the vibration pickup means 5 provided inside the weight member 16 and the microphone There is no deviation from the noise component caused by the external vibration generated in the unit 3.
A signal pin (not shown) is held in the pin holder 13 and is connected to the microphone unit 3 by a lead wire (not shown).

The subassembly 1A configured as described above is accommodated in the microphone case 2 as shown in FIG.
The microphone case 2 covers the microphone unit 3 and is connected to a mesh-like head case 2a having a sponge-like pop filter 2b attached to the inner surface thereof, and a lower end of the head case 2a. The surrounding casing 2c and the tail cover 2d that fits the lower end of the casing 2c and covers the lower part of the microphone are configured. The support member 2e is integrally formed with the tail cover 2d.

In the dynamic microphone 1 configured as described above, when a sound wave reaches the microphone unit 3, the voice coil 6 vibrates together with the diaphragm 7 with respect to the magnet 8, and functions as a microphone.
Here, when external vibration is applied to the microphone case 2, the microphone unit 3 vibrates relative to the microphone case 2 against the elasticity of the front shock mount member 11 and the rear shock mount member 12 due to its inertia. . For this reason, in the vibration pickup means 5, an electromotive force is generated in the cancel coil 17 due to disturbance vibration of the cancel coil 17 in the magnetic field of the magnet 15.
On the other hand, an electromotive force is also generated by the external vibration in the voice coil 6 that vibrates together with the diaphragm 7. Only the noise component due to is canceled out.

As described above, according to the dynamic microphone 1 according to the present embodiment, the vibration between the cylindrical weight member 16 that is isolated from the microphone case 2 by the rubber elastic body and the cavity sleeve 4 that supports the microphone unit 3. By picking up the speed difference, the vibration noise in the microphone unit 3 can be canceled.
Further, according to this configuration, the microphone unit 3, the front shock mount member 11, the rear shock mount member 12, and the vibration pickup means 5 are all included in the subassembly 1A. That is, it is possible to construct a configuration that cancels vibration noise before the subassembly 1A is incorporated into the microphone case 2, and adjusts the output of the vibration pickup means after the microphone unit is mounted in the case as in the prior art. There is no need. Therefore, the manufacturing work can be made easier than the conventional microphone that cancels the vibration noise by using the vibration pickup means.

1 dynamic microphone 2 microphone case 3 microphone unit 4 cavity sleeve (unit support member)
5 Vibration pickup means 6 Voice coil 7 Diaphragm 8 Magnet 9 Yoke 11 Front shock mount member 12 Rear shock mount member 15 Magnet 16 Weight member 17 Coil

Claims (1)

A dynamic microphone including a microphone unit that converts sound waves into electric signals based on vibrations of a diaphragm and a voice coil caused by incoming sound waves,
A unit support member for supporting the microphone unit;
A cylindrical weight member that is arranged so as to surround the unit support member and supports the unit support member via an elastic member;
The voice coil of the microphone unit, as well as have the cancel coils connected as opposite phases connected to each other with respect to external vibration, a magnet and a corresponding said cancel coils, said unit supporting said weight member side Vibration pickup means arranged to face each other on the member side;
A microphone case that houses the microphone unit, the unit support member, the weight member, and the vibration pickup means;
The dynamic microphone characterized in that the microphone case supports the weight member accommodated in the internal space via an elastic member .

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