KR20020024123A - Directional capacitor microphone - Google Patents

Abstract

The present invention is to ensure a sufficient sensitivity difference between the front sound and the rear sound in the case of a single direction, and in the case of bidirectional, the rear sound inflow structure is designed on the outer periphery of the metal case body and the PCB so that any rear sound on the PCB The present invention relates to a directional condenser microphone, which excludes a through groove so that an electric contact area can be enlarged and dust / fog can be prevented from entering.

According to the present invention, in the case of a single-directional microphone, a rear sound inflow structure is designed at the outer periphery of the case body and the PCB, and a sintered filter for attenuating the rear sound is formed in a cylindrical shape to have a function of a polarization holder, and the polarization thereof. The rear sound passing through the holder is configured to reach the diaphragm through the rear sound passing hole of the ring-shaped connector, so that the sensitivity difference between the front sound and the rear sound flowing from the front of the case body as the inlet path of the rear sound is extended as a whole. Not only will it be sufficiently obtained, but no back pain passage will be formed on the PCB, preventing the ingress of dust and foreign matter.

In addition, in the case of the bidirectional microphone, a structure is designed for inflow of rear sound between the case body and the outer circumferential end of the PCB, and the diaphragm reaches the diaphragm through the rear sound inlet and the rear sound passage formed in the bipolar holder and the ring-shaped connector. No back pain passage groove is formed on the PCB to prevent inflow of dust / foreign material from the outside.

Description

Directional Condenser Microphone {DIRECTIONAL CAPACITOR MICROPHONE}

The present invention relates to a directional condenser microphone, and more particularly, to a directional condenser microphone for providing a unidirectional structure in which the sensitivity difference between the front sound and the rear sound is optimized and the effective contact area of the PCB terminal part is maximized. It is about.

In general, a microphone for converting a voice into an electrical signal is essentially adopted in an audio device for receiving and processing external sound or a communication device (particularly, a mobile communication terminal) for exchanging voice.

1 is a view for explaining the outline of a general directional condenser microphone.

In the drawing, the metallic casing denoted by 10 is usually made of aluminum and seals / compresses the components of the corresponding directional microphone so that foreign substances do not enter from the outside, and a protective cap prevents the inflow of external electrical noise. Will have

Diaphram, denoted by 12, is usually formed by vacuum evaporation of Ni on PET or PPS film and vibrates by sound waves while maintaining a small distance from the back plate, which will be described later. It acts to cause a change in capacity.

A polar ring, denoted by 12a, is produced by, for example, punching a SUS304 panel into a press mold and is typically used for the support of the diaphragm 12.

The back plate indicated by 14 is manufactured by pressing a panel in which a FEP film is adhered to an SUS plate with a press mold so that a plurality of sound wave inlet holes 14a are formed on the upper surface thereof, and are usually charged and discharged at a high voltage of several KV. It serves as a plate, whose charging potential determines the sensitivity of the corresponding directional microphone and the phenomenon is referred to as an 'electret'.

The spacer labeled 16 is interposed between the diaphragm 12 and the back plate 14 to serve as a gap body and an electrical insulator to maintain a constant gap therebetween, and is usually produced by punching a PET film into a press mold. do.

In addition, the ring-shaped connector shown at 18 has a function of electrically connecting the gate of the field effect transistor (FET) to be described later and the back plate 14, and usually after pressing brass, It is prepared by plating.

The bipolar holder (I.R ring) indicated by 20 is assembled with the back plate 12 and the ring-shaped connector 18 to act as a mechanical support and an insulator, and is preferably manufactured by injection molding of ABS material.

The FET denoted by 22 serves as an impedance converter that transmits a change signal to an amplifier (not shown) in the subsequent stage, resulting in a change in electrical capacitance as a change in impedance.

In addition, the PCB denoted by 24 has a plurality of rear sound passing holes 24a formed as the rear cover and the output terminal of the corresponding directional microphone, and is composed of a contact type, a pin type, and a soldering type according to the use thereof.

The sintered filter indicated by 26 is a resistor for sound, and has a function of attenuating the sound passing through the rear sound passing hole 24a of the PCB 24 so that the corresponding directional microphone has a directing characteristic.

The front filter, marked 28, is usually formed of a non-woven fabric to prevent the ingress of dust or foreign matter inside the corresponding directional microphone.

FIG. 2 shows an electrical equivalent circuit diagram of the directional microphone shown in FIG. 1.

Referring to FIG. 3A, when the directional microphone illustrated in FIG. 1 is unidirectional, the front sound 30 passes through the front filter 28 and passes through the sound wave inlet of the metallic case body 10. 10a) to vibrate the diaphragm 12, and when a distance change occurs between the back plate 14 due to the vibration of the diaphragm 12, a change in capacitance with respect to the distance change results in the FET ( 22 to detect a voice signal.

On the other hand, the back sound 32 is attenuated directly through the sintered filter 26 as a sound wave resistor via the back sound through hole 24a of the PCB 24, and the attenuated sound wave is attenuated by the diaphragm 12. Vibrate).

Therefore, the rear reflection sound has a smaller level than the front sound, so that the omnidirectional microphone has an omnidirectional characteristic. Such a monodirectional microphone exhibits a frequency response characteristic diagram shown in FIG. 4A.

Referring to FIG. 3B, when the directional microphone illustrated in FIG. 1 is bidirectional, the front sound 30 ′ for the corresponding bidirectional microphone in the state in which the sintered filter 26 is excluded will be described above. Passed through the front filter 28 to the sound wave inlet (10a) of the metallic case body 10 to vibrate the diaphragm 12, the vibration of the diaphragm 12 with the back plate 14 The change in capacitance corresponding to the distance change that occurs between is detected by the FET 22 to detect a voice signal.

On the other hand, the rear sound 32 'vibrates the diaphragm 12 via the rear sound passage hole 24a of the PCB 24.

In such a bidirectional microphone, when the sound pressures of the front sound and the back sound are the same, the diaphragm 12 is not vibrated, so that the bidirectional microphone is generally bi-directional, and FIG. 4B shows the frequency response characteristic of the bidirectional microphone. .

By the way, in the case of the unidirectional microphone, as the rear sound 32 passes through the sintering filter 26 via the rear sound passing hole 24a of the PCB 24, the front sound ( The sensitivity difference between 30) and the back sound 32 is not sufficiently secured, so that it is difficult to obtain an optimal single-directional effect.

In addition, since the rear sound passing hole 24a is formed on the PCB 24, dust or foreign matter is easily introduced into the metallic case body 10, so that the induction rate of electrical noise is increased. Will be shown.

In addition, since the polarization holder 20 and the sintering filter 26 are formed as separate components inside the metallic case body 10, not only are affected by the miniaturization of the overall dimensions thereof, but also the manufacturing labor and manufacturing cost thereof. Rises.

In addition, in the case of the bidirectional microphone, as the rear sound through hole 24a is formed on the PCB 24, the electrical contact area is not only limited, but also through the rear sound through hole 24a. It has a structure that is vulnerable to the inflow of foreign matters.

Accordingly, the present invention has been made in view of the above-described circumstances of the prior art, and the first object thereof is to provide a rear sound through hole formed at the crimping portion of the metallic case body and the PCB in the case of a single orientation to prevent dust or foreign matter from entering. While the rear sound passage is extended, the sensitivity difference between the front sound and the rear sound is increased, and the sintered filter also has the function of a polarization holder so that it can be miniaturized as a whole, thereby reducing manufacturing man-hours and costs. It is to provide a condenser microphone.

The second object of the present invention is to make the rear sound through hole is formed in the metal case body and the crimping part of the PCB in the case of bi-directional, so as to prevent the inflow of dust or foreign matter and to prevent the rear sound through hole is formed on the PCB electrical contact It is to provide a directional condenser microphone designed to ensure a sufficient area.

In order to achieve the above-mentioned first object, according to the first embodiment of the present invention and the sound wave inlet for the passage of the front sound is formed on one surface and the case body having a diaphragm disposed through the diaphragm support ring in the lower side thereof; The back plate is formed at a predetermined interval through the spacer with respect to the diaphragm while a back sound through hole is formed for the passage of the rear sound, which causes a change in capacitance with respect to a distance change with the diaphragm, and is disposed inside the case body. A sintered filter for attenuating the rear sound while defining a bipolar chamber, a ring-shaped connector disposed inside the sintered filter to form a rear sound passage for passing the rear sound, and the back plate via the ring-shaped connector. An FET that is electrically connected to the FET to detect a change in capacitance from its backplate as an electrical voice signal The implementation is a directional microphone configured including PCB which is the rear sound passing through the path is defined for the passage of the rear sound on the peripheral edge for crimping with the case body is provided.

According to the present embodiment, the rear sound passing groove of the ring-shaped connector is formed in a shape cut at one end thereof so that the rear sound is guided to the diaphragm.

In addition, the outer periphery end of the PCB is formed with a rear sound through groove for each predetermined position to extend the inflow path of the rear sound, and the upper and lower surfaces of the rear of the rear sound through groove are tapered to a constant depth and the rear penis. It is formed as a rojo part.

Therefore, in the directional microphone according to the first embodiment of the present invention, the front sound path is formed to extend into the diaphragm through the double pole holder and the ring-shaped connector when the rear sound inflow path formed between the outer peripheral end of the PCB and the case body is unidirectional. The difference in sensitivity between the sound and the back sound is satisfactorily ensured, so that the unidirectional effect is remarkably improved.

In order to achieve the above-described second object, according to the second embodiment of the present invention, while the sound wave inlet for the passage of the front sound is formed on one surface thereof, the inner case lower body through the diaphragm support ring, and the diaphragm is disposed; While defining the inflow path of the rear sound at the crimping part of the case body, the PCB having the FET mounted thereon for outputting an electrical voice signal, and the diaphragm are spaced at regular intervals through a spacer for the passage of the rear sound. A back plate through which a back sound passing hole is formed to cause a change in capacitance with respect to a change in distance from the diaphragm, and disposed inside the case body to define a polarization chamber, is provided for the rear sound passing between the case body and the PCB. A back holder having a rear sound passage for passing therethrough, the rear sound being disposed inside the sintering filter and passing through the rear sound Gwahom is formed a directional microphone configured by a ring-shaped connector for electrically connecting the PCB and the back plate is provided.

According to this embodiment, the outer periphery end of the PCB is formed with a rear sound through groove for each predetermined position to extend the inflow path of the rear sound, and the upper and lower surfaces of the rear of the rear sound through groove tapered to a constant depth It is processed to form the rear penis recess.

In addition, the sound wave passing groove formed in the ring-shaped connector is formed to communicate with the back sound passage formed in the polarization holder.

In the directional microphone according to the second embodiment of the present invention, in the case of bidirectional orientation, as the rear sound inflow path is defined at the crimping portion of the case body and the PCB, no groove for any rear sound passage is formed on the PCB. The electrical contact area can be expanded while preventing the inflow of dust or foreign substances from the outside.

1 is a view for explaining the outline of a general directional microphone,

2 is an electrical equivalent circuit diagram of the directional microphone shown in FIG. 1;

3A is a view for explaining the operation when the directional microphone shown in FIG. 1 is unidirectional;

3B is a view for explaining the operation when the directional microphone shown in FIG. 1 is bidirectional;

4A is a frequency response characteristic diagram of the unidirectional microphone shown in FIG. 3A;

4B is a frequency response characteristic diagram of the bidirectional microphone shown in FIG. 3B;

5 is a view showing an example in which the directional condenser microphone according to the present invention is configured as a unidirectional structure;

6A is a view showing the structure of a metallic case body constituting a directional condenser microphone according to the present invention;

6B is a view for explaining the structure of a PCB constituting the directional condenser microphone according to the present invention;

6C is a view for explaining the structure of the ring-shaped connector constituting the directional condenser microphone according to the present invention;

7 is a view showing an example in which the directional condenser microphone according to the present invention is configured as a bidirectional structure.

* Description of the symbols for the main parts of the drawings *

10: metallic casing, 12: diaphragm,

14: back plate, 18: ring-shaped connector,

20: polarization holder, 22: FET,

24: PCB, 26: sintered filter,

40, 70: metallic casing, 44, 74: diaphragm,

48,78: backplate, 52,82: FET,

54: sintered filter, 56, 86: PCB,

84: double pole holder.

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

5A is a cross-sectional structural view of a unidirectional microphone according to a first preferred embodiment of the present invention.

Referring to the drawings, a sound wave inlet 42b for inflow of the front sound 42a is formed on one surface (that is, the lower side of the figure) of the metallic case body 40, and the inner bottom surface (that is, the lower side of the figure) is formed. The diaphragm 44 supported by the diaphragm support ring 44a is disposed.

In addition, the back plate 48 is formed on the diaphragm 44 at a position spaced apart from the diaphragm 44 by a spacer at a predetermined interval, and the back plate 48 is formed on the diaphragm 44. A change in capacitance with respect to the distance change of the, and on the back plate 48, the rear sound passing hole (48a) for the passage of the rear sound 50 is formed.

The FET 52 which generates an electrical voice signal based on the capacitance detected by the back plate 48 is disposed in the double-sided chamber formed above the back plate 48.

According to the present invention, the sintered filter 54 for attenuating the rear sound is disposed on the spacer 46 in the metallic case body 40, and the sintered filter 54 also has a function of a double pole holder. It is formed in a cylindrical shape (see FIG. 6A).

In addition, referring to FIG. 5A, a ring-shaped connector electrically connecting the back plate 48 and the PCB 56 mounted with the FET 52 to the inside of the sintered filter 54 having the function of the polarization holder. 58 is disposed.

According to the present invention, preferably, at the lower end of the ring-shaped connector 58, a rear sound passage groove 58a for the passage of the rear sound is formed (see FIG. 6B).

Further, according to the present invention, the rear sound passage groove 56a is formed at the outer peripheral end of the PCB 56 at a predetermined position in order to extend the inflow path of the rear sound 50. ) Is formed by the rear surface path recessed portion 56b by tapering the upper and lower surfaces thereof to a certain depth (see FIG. 6C).

Therefore, when the outer periphery of the PCB 56 is compressed to the metallic case body 40, the path of the rear sound 50 is the rear sound path recess 56b of the PCB 56 and the rear sound passage groove ( It passes through the sintering filter 54 and the back sound passing hole 48a of the back plate 48 via 56a, and then extends to reach the diaphragm 44.

That is, in the unidirectional microphone according to the first embodiment of the present invention, the front sound 42a passes through the sound wave inlet 42b of the metallic case body 40 to vibrate the diaphragm 44, and the diaphragm ( The change in capacitance corresponding to the distance change with the back plate 48 is sensed by the FET 52 by the vibration of 44.

On the other hand, the rear sound 50 is introduced through the rear sound path recess 56b and the rear sound passage recess 56a formed at the outer circumferential end of the PCB 56 to provide the sintered filter 54 having the polarization holder function. After being attenuated through the diaphragm 44, the diaphragm 44 is vibrated by passing through the rear sound passing groove 58a of the ring-shaped connector 58 and the rear sound passing hole 48a of the back plate 48.

Therefore, the rear sound 50 has a smaller level than the front sound 42b, so that the omnidirectional omnidirectional effect is remarkably improved.

In addition, since the groove for the rear passage through which the rear sound 50 directly flows is not formed on the PCB 56, dust or foreign matter is prevented from being introduced from the outside, thereby suppressing the induction rate of electrical noise.

Furthermore, as the sintered filter 54 is designed to have the function of a polarization holder, shortening of manufacturing man-hours and reduction of manufacturing cost and number of parts are also expected.

7 is a cross-sectional structural view showing a bidirectional microphone according to a second preferred embodiment of the present invention.

Referring to the drawings, a sound wave inlet 72b for inflow of the front sound 72a is formed on one surface (that is, the lower side of the figure) of the metallic case body 70, and the inner bottom surface (that is, the lower side of the figure) is formed. The diaphragm 74 supported by the diaphragm support ring 74a is disposed.

The back plate 78 is formed on the diaphragm 74 at a position spaced apart from the diaphragm 74 by a spacer at a predetermined interval, and the back plate 78 is a distance from the diaphragm 74. It causes a change in capacitance with respect to the back plate 78, the rear sound passing hole 78a for the passage of the rear sound 80 is formed.

In addition, an FET 82 for generating an electric voice signal based on the capacitance detected by the back plate 78 is disposed in the polarization chamber formed above the back plate 78.

In addition, a rear holder 84 is disposed on the spacer 76 in the metallic case body 40, and the rear holder passes through the rear holder 84 for the passage of the rear sound 80. 84a is formed.

A ring-shaped connector 88 for electrically connecting the back plate 78 and the PCB 86 on which the FET 82 is mounted is disposed inside the bipolar holder 84. The ring-shaped connector 88 At the top of the back) is formed a rear sound passing groove (88a) in the form that is in communication with the rear sound passage (84a) formed in the polarization holder 84 (see Fig. 6b).

In addition, according to the present invention, in order to extend the inflow path of the rear sound 80 in the form shown in Figure 6c at the outer circumferential end of the PCB 86, the rear sound through groove is formed at the predetermined position and the rear sound The rear of the through groove is tapered to a certain depth of the upper surface and the lower surface is formed as the rear path recess.

Therefore, in the bidirectional microphone illustrated in FIG. 7, the front sound 72a passes through the sound wave inlet 72b of the metallic case body 70 to vibrate the diaphragm 74, and the vibration of the diaphragm 74. The change in capacitance corresponding to the change in distance between the back plate 78 is sensed by the FET 82.

On the other hand, the rear sound 80 is introduced through the rear sound path recess and the rear sound passage recess (refer to FIG. 6C) formed at the outer circumferential end of the PCB 86, and the rear sound passage 84a of the polarization holder 84 is provided. And the diaphragm 74 through the rear sonic passage 88a of the ring-shaped connector 88 which communicates with the rear somatic passage 84a.

In this case, when the sound pressures of the front sound 42a and the rear sound 80 are the same, the diaphragm 74 does not vibrate, and thus the bidirectional characteristic of the '8' shape is shown.

Therefore, in the bidirectional microphone illustrated in FIG. 7, since a groove for any rear sound passage is not formed in the effective surface of the terminal portion on the PCB 86, the electrical contact area is sufficiently secured, and dust or foreign matter is introduced from the outside. This is avoided.

As described above, according to the directional condenser microphone according to the present invention, the unidirectional effect is remarkably improved and sintered since the inflow path of the rear sound is extended in the unidirectional case so that the sensitivity difference between the front sound and the rear sound is sufficiently ensured. As the filter is designed to have the function of a polarization holder, it is possible to shorten the overall manufacturing man-hour, reduce the number of parts and manufacturing cost, and because there is no groove for direct passage of the back sound on the PCB, Inflow is prevented and the induction rate of electrical noise is also suppressed.

In addition, according to the present invention, since no groove is formed on the PCB for the passage of the rear sound, the electrical contact area is sufficiently secured, and dust and foreign matters are prevented from being introduced from the outside.

Claims (8)

A case body having a diaphragm disposed through a diaphragm support ring on a lower side thereof while a sound wave inlet for a front sound is formed on one surface thereof; The back plate is formed spaced apart at regular intervals through the spacer with respect to the diaphragm to form a rear sound passing hole for the passage of the rear sound, causing a change in capacitance with respect to the distance change with the diaphragm, A sintered filter disposed inside the case to define a rear chamber and attenuate the rear sound; A ring-shaped connector disposed inside the sintering filter and having a rear sound passing groove for passing the rear sound; The FET which is electrically connected to the back plate via the ring-shaped connector and detects a change in capacitance from the back plate as an electric voice signal is mounted, and the rear sound is formed at an outer circumferential end for crimping with the case body. Directional condenser microphone, characterized in that it comprises a PCB for defining the back pass path for the passage of. The directional condenser microphone according to claim 1, wherein the rear sound passing groove of the ring-shaped connector is formed in a shape cut at one end thereof so that the rear sound is guided to the diaphragm. According to claim 1, wherein the outer periphery of the PCB is formed in the rear sound through groove for each predetermined position in order to extend the inflow path of the rear sound, the upper and lower surfaces of the rear of the rear sound through groove tapered to a constant depth A directional condenser microphone, characterized in that the processing is formed by the rear penis path recess. 4. The directional condenser microphone according to any one of claims 1 to 3, wherein the corresponding microphone is unidirectional. A case body having a diaphragm disposed through a diaphragm support ring on a lower side thereof while a sound wave inlet for a front sound is formed on one surface thereof; PCB having an FET mounted thereon to define an inflow path of the rear sound at the crimping part of the case body and output an electrical voice signal on one surface thereof; The back plate is formed spaced apart at regular intervals through the spacer with respect to the diaphragm to form a rear sound passing hole for the passage of the rear sound, causing a change in capacitance with respect to the distance change with the diaphragm, A polarization holder disposed inside the case body and defining a rear chamber, and having a rear sound passage for passing the rear sound passing between the case body and the PCB; And a ring-shaped connector disposed inside the sintering filter to form a rear sound passing groove for passing the rear sound and electrically connecting the back plate and the PCB. According to claim 5, The outer periphery of the PCB is formed in the rear sound through groove for each predetermined position to extend the inflow path of the rear sound, the upper and lower surfaces of the rear of the rear sound through groove tapered to a constant depth A directional condenser microphone, characterized in that the processing is formed by the rear penis path recess. 6. The directional condenser microphone according to claim 5, wherein the sound wave passing groove formed in the ring-shaped connector is formed to communicate with the rear sound passing hole formed in the polarization holder. 8. The directional condenser microphone according to any one of claims 5 to 7, wherein the corresponding microphone is bidirectional.