KR100464700B1 - Electret condenser microphone - Google Patents

Abstract

The present invention relates to a directional condenser microphone capable of thinning the overall dimensions while securing a sufficient difference in sensitivity between front and rear sounds by employing a high density PTFE filter of several hundred microns instead of a relatively thick sintered filter.

According to a preferred embodiment, a plurality of rear sound inlet holes are formed on the bottom surface of which a FET for detecting a voice signal is disposed, and a plurality of front sound through holes on one surface are formed in an outwardly expanding shape on the annular indentation part. A sieve, a back plate installed on the inner bottom surface of the metallic case body through a metal ring member, and having a plurality of sound wave passing holes, and a diaphragm arranged so that the diaphragm is kept at a constant distance from the back plate via a spacer. A metal ring disposed in contact with an inner contact ring, a metal ring member disposed inside one surface of the back plate and the metallic case body to define a resonance space, and bonded to an outer side of a bottom surface of the metallic case body, It consists of a PTFE filter as an acoustic resistor for attenuation.

Description

Directional Condenser Microphone {ELECTRET CONDENSER MICROPHONE}

The present invention relates to a directional condenser microphone, and more particularly, to a directional condenser microphone to maximize the directivity characteristics by adopting a PTFE filter to optimize the sensitivity difference between the rear and front sounds in a single direction.

In general, a microphone is essential for converting the sound into an electrical signal in an audio device that receives and post-processes a sound from the outside or a communication device (especially, a mobile communication terminal) for exchanging sound.

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 formed of aluminum to seal / compress the components of the corresponding directional condenser microphone to prevent foreign substances from being introduced from the outside and to prevent the inflow of external electrical noise. It has a function.

The diaphragm on the front surface indicated by 12 is usually formed by vacuum evaporation of Ni on PET or PPS film, and the electrostatic electrostatic discharge is caused by vibration caused by sound waves from the outside while maintaining a small distance from the back plate described later. It acts to lead to a change in dose.

In addition, a polar ring indicated by 12a is manufactured by, for example, punching a SUS304 panel into a press mold and is generally employed for supporting the diaphragm 12.

The back plate indicated by 14 is manufactured by pressing a panel in which a FEP film is adhered to a SUS plate with a press mold so that a plurality of sound wave inlet holes 14a are formed on the upper surface thereof, and is usually charged at a high voltage of several KV to serve as a bipolar plate. The charging potential determines the sensitivity of the corresponding directional condenser 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 the spacer is usually a press mold. It is made by punching.

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

An IR ring denoted by 20 is assembled with the back plate 12 and the ring-shaped connector 18 to act as a mechanical support and an insulator. Preferably, the anode holder 20 is made of ABS material. It is manufactured by injection molding.

The FET denoted by 22 serves as an impedance converter which transmits the signal of the change to the amplifier (not shown) of the rear end as a result of the change in the capacitance of the diaphragm 12 as the change in the impedance.

The PCB marked 24 is formed with a plurality of back through holes 24a, which serve as a rear cover and an output terminal of a corresponding directional condenser microphone, and are composed of a contact type, a pin type, and a soldering type according to the purpose.

The sintered filter indicated by 26 is a resistance to sound, and attenuates the sound passing through the rear sound passing hole 24a of the PCB 24 so that the corresponding directional condenser microphone has a directing characteristic.

Here, the front filter of the directional condenser microphone shown in Figure 1 is generally formed of a nonwoven fabric in order to prevent the infiltration of dust or foreign matter inside.

2 shows an electrical equivalent circuit for the directional condenser microphone of the above-described configuration.

Referring to FIG. 3, when the directional condenser microphone illustrated in FIG. 1 is unidirectional, the front sound 30 passes through the front filter to pass the sound wave inlet 10a of the metallic case body 10. The oscillation plate 12 is vibrated to vibrate, and when a distance change is generated between the diaphragm 12 and the back plate 14 due to the vibration of the diaphragm 12, the change in capacitance with respect to the distance change is the FET 22. Is detected as a signal corresponding to the sound at "

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).

Accordingly, the rear reflection sound has a smaller level than the front sound, and thus has omnidirectional omnidirectional characteristics. Such a monodirectional microphone has a frequency response characteristic according to frequency shown in FIG. 4.

However, in the case of the unidirectional condenser microphone, the front surface of the unidirectional condenser microphone is set so that the rear sound 32 passes through the sintering filter 26 via the rear sound passing hole 24a of the PCB 24. The difference in sensitivity between the sound 30 and the back sound 32 is not sufficiently ensured, making it difficult to obtain an optimal single-directional effect.

In addition, the sintered filter 26 in the metallic case body 10 needs a certain thickness to sufficiently attenuate the front sound 30 and the rear sound 32, thereby miniaturizing its overall dimensions. In addition to affecting, the directional sintering characteristics of the sintered filter 26 are highly likely to occur depending on the degree of sintering.

Accordingly, the present invention has been made in view of the above-described circumstances of the prior art, and its first object is to have a fine thickness (hundreds of microns) as an acoustic resistor on the outer surface of the metallic case body in place of the front filter by the nonwoven fabric in the case of unidirectionality. The high density PTFE filter provides a directional condenser microphone designed to reduce the manufacturing cost and cost by increasing the sensitivity difference between the rear and front sounds and miniaturizing the overall dimensions.

The second object of the present invention is to reverse the position of the diaphragm as the back plate and the diaphragm, and to place a metal ring between the back plate and the inner side of the metallic case body so that a sufficient resonance space is secured so that the output level can be compensated. While the PCB is formed in the sound wave inlet type to provide a directional condenser microphone that is advantageously applied to the main board contact structure or surface mounting work of the sound wave inlet.

In order to achieve the above object, according to a preferred embodiment of the present invention, a plurality of rear sound inlet holes are formed and a bottom surface of which a FET for detecting a voice signal is disposed, and a plurality of front sound through holes on one surface are annular. The metallic case body formed in the outward expansion shape in the press part, the back plate which is installed on the inner bottom surface of the metallic case body via a metal ring member and has a plurality of sound wave passing holes, and the diaphragm is spaced apart from the back plate by a spacer. A diaphragm disposed to hold a metal ring, a metal ring disposed on the diaphragm and contacting an inner contact ring, a metal ring member disposed inside one surface of the back plate and the metallic case body and defining a resonance space, and the metallic case body It is adhered to the outside of the bottom of the made of PTFE filter as an acoustic resistor for attenuation of the front sound Directional condenser microphones are provided.

Preferably, the diaphragm is disposed so that the rear sound directly vibrates the diaphragm through the rear inlet hole of the PCB.

The diaphragm is connected to the FET through the metal ring, and the back plate accumulates electric charges and is in electrical contact with the metallic case body through the metal ring member to form an electric circuit.

According to the invention, the corresponding microphone is formed unidirectional.

According to another embodiment of the present invention, a plurality of rear sound inlet holes are formed and a bottom surface thereof has a PCB on which a FET for detecting a voice signal is disposed, and a plurality of front sound through holes on one surface thereof are formed in an outwardly expanding shape in an annular indentation portion. A metal case body formed with charge and a diaphragm arranged so as to maintain a constant distance between the diaphragm and the diaphragm with respect to the bottom surface of the metal case body, a metal ring disposed on the diaphragm and contacting the inner contact ring, A metal ring member for conducting a diaphragm and a metal ring to one inner surface of the metallic case body, and defining a resonance space, and PTFE as an acoustic resistor for attenuating the front sound by being bonded to the outer side of the one surface of the metallic case body. A directional condenser microphone made of a filter is provided.

Preferably, according to this embodiment the microphone is formed unidirectional.

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

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

3 is a frequency response characteristic diagram of a unidirectional condenser microphone;

4 is a frequency response response characteristic of a unidirectional capacitor;

5A is a view showing an example in which a directional condenser microphone according to a preferred embodiment of the present invention has a structure of a back electret type reverse unidirectional microphone;

FIG. 5B is a view showing an example in which the directional condenser microphone according to the present invention has a structure of a front electret type reverse unidirectional microphone; FIG.

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

7 is a view for explaining a ring-shaped metal ring member constituting the directional condenser microphone according to the present invention.

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

10,50: metallic case body, 12,62a: diaphragm,

14,66: back plate, 18: ring-shaped connector,

22,56: FET, 24,52: PCB,

26: sintered filter, 70: metal ring member,

72: PTFE filter.

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

Fig. 5A shows a configuration in which the directional condenser microphone according to the preferred embodiment of the present invention has a structure of a back electret type reverse unidirectional condenser microphone.

That is, referring to Figure 5a, the PCB 52 having the output terminal function disposed inside the metallic case body 50 is formed with a plurality of rear sound inlet holes (52a) for the passage of the rear sound (54), The FET 56 is disposed on the bottom of the PCB 52.

In addition, the outer circumferential end of the diaphragm 62a is adhered to the lower side of the metal ring 60 in contact with the inner contact ring 58 disposed so that the resonance space P is sufficiently secured inside the metallic case body 50. Diaphragm 62 is disposed.

The back plate 66 in which charge is charged through the spacer 64 is disposed below the diaphragm 62, and a plurality of sound wave passing holes 66a are formed in the back plate 66. Here, the back plate 66 causes a change in capacitance with respect to a distance change with the diaphragm 62a while maintaining a constant distance from the diaphragm 62a by the spacer 64.

In addition, according to the present invention, a metal ring member 79 is disposed between the back plate 78 and the bottom surface of the metallic case body 50. The metal ring member 79 is formed of a corresponding directional condenser microphone. Resonance space is provided to sufficiently compensate the output level.

In addition, according to the present invention, the bottom surface of the metallic casing 50 is pressed in an annular band shape for increasing the sensitivity of the corresponding reverse unidirectional condenser microphone, and then the front sound 68 is introduced into the annular compression end. A plurality of front sound inlet hole (50a) is formed in the form that is outwardly expanded (see Figure 6).

In addition, a high density PTFE filter 72 having a thickness of several hundred microns, which acts as an acoustic resistor, is bonded to the outside of the bottom of the metallic case body 50.

Here, as shown in FIG. 5A, the diaphragm 62 is connected to the FET 56 through the metal ring 60, and the back plate 66 accumulates electric charges and the metal ring member 70. An electrical circuit is formed by electrically contacting the bottom surface of the metallic case body 50 (see FIG. 7).

Thus, the above-described structure provides a unidirectional condenser microphone which exhibits a rearward directing effect.

According to the unidirectional condenser microphone shown in FIG. 5A, the rear sound 54 is introduced through the rear sound inlet hole 52a of the PCB 52 to vibrate directly to the diaphragm 62a, and the diaphragm 62a. The change in capacitance corresponding to the change in distance between the back plate 66 due to the vibration of c) is detected by the FET 56 to obtain a corresponding audio signal.

On the other hand, the front sound 68 is attenuated by the PTFE filter 72 as the acoustic resistor, and then the sound wave passage of the back plate 66 via the front sound inlet hole 50a of the metallic case body 50. The front sound 68 is attenuated by the PTFE filter 72 as the sound wave resistor, and thus the level of the front sound 68 is lower than that of the rear sound 94 through the 66a. The reverse unidirectional effect is greatly improved.

Fig. 5B shows an example in which the directional condenser microphone according to the present invention is constituted by the structure of the front electret unidirectional condenser microphone.

Referring to the drawings, as compared to the structure shown in Figure 5a the back plate is removed, the metallic case body 50 has a bipolar plate function, accordingly the metal ring 60 in contact with the inner contact ring 58 And the diaphragm 62 are connected to the bottom surface of the metallic case body 50 via the metal ring member 70 (see FIG. 7).

Accordingly, even in the case of the front electret type unidirectional condenser microphone illustrated in FIG. 5B, the rear sound 54 passes through the rear sound inlet hole 52a of the PCB 52 to vibrate the diaphragm 62a. The change in capacitance corresponding to the change in distance from the diaphragm 62a is detected by the FET 56 from the metallic case body 50 to obtain a corresponding audio signal.

On the other hand, the front sound 68 is attenuated by the PTFE filter 72 as the acoustic resistor and then transmitted to the diaphragm 62a via the front sound inlet hole 50a of the metallic case body 50. As the front sound 68 is attenuated by the PTFE filter 72 as the sound wave resistor, the level becomes smaller than that of the rear sound 94 so that the reverse unidirectional effect is remarkably improved.

On the other hand, the present invention is not limited to the above embodiments, and various changes and modifications are possible without departing from the technical gist and gist of the invention. For example, although the inner contact ring and the metal ring are separately configured with respect to the diaphragm, the inner contact ring may be integrated with the diaphragm.

As described above, according to the directional condenser microphone according to the present invention, by using a high-density PTFE filter having a thickness of several hundred microns in place of the sintered filter by the nonwoven fabric as an acoustic resistor, sufficient sensitivity difference between the front sound and the back sound is ensured. Thus, the unidirectional effect is remarkably improved.

In addition, according to the present invention, since the PTFE filter as the acoustic resistor has a fine thickness, it is possible to manufacture a thin product as a whole as compared with the case of employing a sintered filter having a thickness of about several millimeters.

Claims (6)

A PCB having a plurality of rear sound inlets formed thereon and a FET disposed thereon for detecting a voice signal; Metal case body formed in the form of outward expansion on the annular indentation portion of the plurality of front through holes on one side, A back plate installed on the inner bottom surface of the metallic case body through a metal ring member and having a plurality of sound wave passing holes formed therein; A diaphragm arranged such that a diaphragm is spaced from the back plate by a spacer, A metal ring disposed on the diaphragm and contacting an internal contact ring, A metal ring member disposed inside one surface of the back plate and the metallic case and defining a resonance space; A directional condenser microphone, comprising: a PTFE filter bonded to an outer side of a bottom surface of the metallic case body as an acoustic resistor for attenuation of the front sound. The directional condenser microphone according to claim 1, wherein the diaphragm is arranged so that the rear sound directly vibrates the diaphragm through the back sound inlet of the PCB. 2. The method of claim 1, wherein the diaphragm is connected to the FET through the metal ring, and the back plate accumulates electric charges and is in electrical contact with the metallic case body through the metal ring member to form an electrical circuit. Directional condenser microphone 4. The directional condenser microphone according to any one of claims 1 to 3, wherein the corresponding microphone is unidirectional. A PCB having a plurality of rear sound inlets formed thereon and a FET disposed thereon for detecting a voice signal; A metal case body in which charge is charged while a plurality of frontal through holes are formed in an outward expansion shape in an annular indentation part on one surface, Diaphragm disposed so that the diaphragm is maintained at a constant interval via a spacer with respect to the bottom surface of the metallic case body, A metal ring disposed on the diaphragm and contacting an internal contact ring, A metal ring member defining a resonance space while conducting the diaphragm and the metal ring to one surface of the metallic case; A directional condenser microphone, characterized in that it is bonded to the outside of the one surface of the metallic case body made of a PTFE filter as an acoustic resistor for attenuating the front sound. 6. The directional condenser microphone of claim 5, wherein the microphone is unidirectional.