KR100675508B1 - Improved Condenser Microphone - Google Patents

Abstract

The present invention relates to a condenser microphone having a structure in which a spacer is removed by pressing a bipolar plate to face a concave space in a central portion thereof. Such a condenser microphone of the present invention comprises a case of a cylindrical metal with sound holes formed on the front plate; Polar ring of conductor; Vibration membrane; A ring-shaped first base of insulator; A bipolar plate formed by attaching a polymer film to a metal plate, and having a periphery contacting the vibrating membrane and having a concave surface formed in the polymer film surface facing the vibrating membrane toward a central portion thereof; A second base of conductors; And a PCB on which circuit components are mounted and on which connection terminals are formed. Therefore, according to the present invention, the polymer film surface of the bipolar plate facing the vibrating membrane is formed into a concave surface similar to the vibrating shape of the vibrating membrane through a series of processing such as applying a press to the center portion of the bipolar plate, so that the displacement of the vibrating membrane is electric. Sensitivity can be improved by maximizing the conversion to a signal, and the manufacturing cost can be reduced by eliminating parts by removing a spacer to form an insulation space.

Condenser Microphone, Double Plate, Concave, Vibration Membrane, Spacer, Improved Sensitivity

Description

Improved Condenser Microphone

1 is a schematic diagram showing the structure of a conventional typical condenser microphone;

2 shows a first embodiment of a condenser microphone according to the present invention;

3 is a second embodiment of a condenser microphone according to the present invention;

4 is a third embodiment of a condenser microphone according to the present invention;

* Explanation of symbols for main parts of the drawings

102,202,302: Case 104b: Polar ring

104a, 204, 304: diaphragm 106, 206, 306: insulation base

108,208,308: Double plate 110,210,310: Base for conduction

112,212,312: PCB

The present invention relates to a condenser microphone, and more particularly, to a condenser microphone having a structure in which a spacer is removed by directing a bipolar plate to face a concave space in a central portion thereof.

1 is a schematic diagram showing a typical typical condenser microphone.

A typical condenser microphone 10 is, as shown in Fig. 1, a case 11 made of a cylindrical metal with a sound hole 11a formed on the front plate, a polar ring 12b made of a conductor, a vibration membrane 12a, and a spacer. (13), a ring-shaped first base made of an insulator (also referred to as an insulated base: 14), and a bipolar plate (also referred to as a fixed electrode; 15) facing each other with a vibrating membrane 12a and a spacer 13 interposed therebetween, Second base (also referred to as a conductive base: 16) and a PCB 17 having circuit components mounted thereon and connecting terminals formed thereon. It is made by curling the ends. At this time, the polar ring 12b and the vibrating membrane 12a may be bonded to each other to form an integrated body 12. The bipolar plate 15 is an electret type microphone, and the polymer film 15b is attached to the metal plate 15a. To form an electret.

As described above, in the conventional condenser microphone, a spacer 13 made of an insulating material is inserted between the vibration membrane 12a and the bipolar plate 15 to form an air gap for forming an electrode. The air gap has a structure in which a gap between the vibrating membrane 12a and the bipolar plate 15 is kept constant from the center to the edge of the vibrating membrane.

However, in such a conventional structure, there is an unnecessary air gap at the edge portion of the vibrating membrane in which the vibrating membrane is hardly moved, which causes a problem that the sensitivity of the condenser microphone is lowered.

In addition, in the conventional condenser microphone, a spacer is separately required to form a space between the vibrating membrane and the bipolar plate. If such a spacer can be removed, the manufacturing cost can be reduced by reducing the process.

The present invention has been proposed to solve the above problems, by forming a concave space in the bipolar plate to form a condenser microphone (Air gap) between the diaphragm without a spacer to improve the sensitivity microphone The purpose is to provide.

Condenser microphone according to an aspect of the present invention to achieve the above object is a case of a tubular metal formed with a sound hole in the front plate; Polar ring of conductor; Vibration membrane; A ring-shaped first base of insulator; A bipolar plate formed by attaching a polymer film to a metal plate, and having a periphery contacting the vibrating membrane and having a concave surface formed in the polymer film surface facing the vibrating membrane toward a central portion thereof; A second base of conductors; And a PCB on which circuit components are mounted and on which connection terminals are formed.

Condenser microphone according to another aspect of the present invention to achieve the above object is a metal tubular case formed with a sound hole is formed on the front plate and the stepped for supporting the vibration membrane; Vibration membrane; A ring-shaped first base of insulator; A bipolar plate having a structure in which a polymer film is attached to a metal plate to form an electret, and a vibrating membrane is attached to the periphery thereof, and a polymer film surface of the bipolar plate facing the vibrating membrane is formed to have a concave surface deeper toward the center portion; A second base of conductors; And a PCB on which circuit components are mounted and on which connection terminals are formed.

And condenser microphone according to another aspect of the present invention in order to achieve the above object is a metal cylindrical case formed with a sound hole on the front plate and a stepped for supporting the vibration membrane; Vibration membrane; A bipolar plate in which a vibrating membrane is attached to a peripheral portion and a surface facing the vibrating membrane is formed to have a concave surface so as to deepen toward the center portion; A ring-shaped first base made of an insulator for supporting the bipolar plate; A second base of conductors; And a PCB on which circuit components are mounted and on which connection terminals are formed. At this time, the vibration membrane and the bipolar plate may be integrally attached.

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

The condenser microphone according to the present invention forms a concave space on the surface of the bipolar plate facing the vibrating membrane through a series of processes such as applying a press to the center portion of the bipolar plate to form a concave space similar to the vibrating shape of the vibrating membrane. Maximizes the conversion to and at the same time remove the spacer (Spacer) to reduce the number of parts.

That is, when the sound wave introduced from the outside vibrates the diaphragm of the condenser microphone, the vibrating membrane moves, and the edge of the diaphragm is fixed to the polar ring until the first resonance of the diaphragm occurs. You can see that is the largest and smaller toward the edge. Therefore, the present invention makes the air gap forming the electrode of the condenser microphone large and the edge small so that the displacement of the vibration membrane is converted into an electrical signal to increase the sensitivity of the condenser microphone. Furthermore, such a structure may not use a spacer, which is essential for forming an air gap in a conventional condenser microphone, and may attach a vibrating membrane to the bipolar plate to integrate the vibrating membrane and the bipolar plate. The condenser microphone of a simpler structure can be manufactured.

As described above, the condenser microphone having a concave surface formed on the bipolar plate to remove the spacer can have various structures. In the embodiment of the present invention, the first embodiment, which is a basic structure, and a case are formed in the case to form a cross section so that not only the spacer but also the polar ring The second embodiment removed and the third embodiment of the structure in which the conductive film wraps around the bipolar plate will be described.

[First Embodiment]

FIG. 2 is a first embodiment of a condenser microphone according to the present invention, and has a structure in which a spacer facing the vibrating membrane is formed in a concave surface (concave surface) so as to deepen toward the center portion.

2, the condenser microphone 100 of the first embodiment of the present invention is a cylindrical metal case 102 having a sound hole 102a formed on the front plate, a polar ring 104b made of a conductor, and vibration. The membrane 104a, the ring-shaped first base 106 made of an insulator, and the peripheral portion contacting the vibrating membrane 104a, and the surface facing the vibrating membrane 104a has a concave surface formed with a concave surface to deepen toward the center portion. 108, a second base 110 made of a conductor, and a PCB 112 having circuit components mounted thereon and a connecting terminal formed thereon, which are typically laminated in the case 102 and then casing 102. It is prepared by curling the end of.

In addition, the polar ring 104b and the vibrating membrane 104a may be bonded to each other to form an integrated diaphragm 104, and the bipolar plate 108 may have the polymer film 108b attached to the metal plate 108a to form an electret. It is a structure. In FIG. 2, reference numeral 108c denotes a sound hole formed in the bipolar plate 108.

In this first embodiment, one (-) power source of the PCB is applied to the vibrating membrane 104a through the case 102 and the polar ring 104b and the other (+) power source is provided through the second base 110. Is applied to the metal plate (108a) of the conductive film is formed between the cathode plate 108 and the vibrating membrane (104a), and the vibrating membrane (104a) by the polymer film (108b) of the first base 106 and the bipolar plate The bipolar plate 108 is adapted to maintain insulation from each other.

When sound waves are introduced from the outside through the sound holes 102a of the case in the opposite state, the vibrating membrane 104a is adhered to the polar ring 104b, so that the vibrating membrane 104a is formed by sound waves introduced from the outside. When the vibration occurs, the central portion of the vibration membrane has the largest displacement until the first resonance occurs, and the displacement decreases toward the edge portion. At this time, according to the present invention, a concave surface similar to the vibration pattern of the vibration membrane is formed on the surface of the bipolar plate 108 facing the vibration membrane 104a, so that the displacement of the vibration membrane is converted into an electrical signal.

Therefore, the condenser microphone 100 according to the present invention can improve the sensitivity, and can reduce the manufacturing cost by removing the spacer, which is essential in the structure of the conventional condenser microphone.

Second Embodiment

3 is a second embodiment of the condenser microphone according to the present invention. The diaphragm 204 is formed in the bipolar plate 208 so that the surface facing the vibrating membrane 204 becomes deeper toward the center portion, and then the vibrating membrane 204 is formed. The vibration membrane 204 and the bipolar plate 208 are integrally attached to each other.

Referring to FIG. 3, the condenser microphone 200 according to the second embodiment of the present invention includes a metal cylindrical case 202 having a sound hole 202a formed in a front plate and a step 202b formed therein for supporting a vibration membrane. The vibration membrane 204, the ring-shaped first base 206 made of an insulator, and the vibration membrane 204 are attached to the periphery thereof, and a bipolar plate having a concave surface formed so that the surface facing the vibration membrane deepens toward the center portion. 208, a second base 210 made of a conductor, and a PCB 212 on which circuit components are mounted and a connection terminal is formed. Typically, the components are sequentially stacked in the case 202, and then, It is made by curling the ends. At this time, the bipolar plate 208 has a structure in which the polymer film 208b is attached to the metal plate 208a to form an electret, and at the edge of the bipolar plate 208 in which the spherical step is formed, the vibration membrane 204 is formed. In addition, the polar rimg, which is required to fix the vibrating membrane 204 in the conventional condenser microphone, can be replaced by attaching the N-type. In this case, a cross section should also be formed in the center of the case 202 surface in contact with the vibrating membrane so that the vibrating membrane 204 does not touch the case 202. In FIG. 3, reference numeral 208c denotes a sound hole formed in the bipolar plate 208.

In this second embodiment, one (-) power source of the PCB is applied to the vibrating membrane 204a through the step surface 202b of the case 202, and the other (+) power source is distributed through the second base 210. It is applied to the metal plate 208a of the pole plate to form a capacitance between the double plate 208 and the vibrating membrane 204, and the vibrating membrane 204 by the polymer film 208b of the first base 206 and the double plate. And the bipolar plate 208 can be insulated from each other.

When sound waves are introduced from the outside through the sound holes 202a of the case in the opposite state, when the vibrating membrane 204 vibrates by the sound waves introduced from the outside, the central portion of the vibrating membrane is largest until the first resonance occurs. It has a displacement, and the displacement becomes smaller toward the edge. In this case, a concave surface similar to the vibration pattern of the vibration membrane is formed on the surface of the bipolar plate 208 facing the vibration membrane 204 to maximize the displacement of the vibration membrane into an electrical signal.

Therefore, the condenser microphone according to the present invention can improve the sensitivity, and it is possible to reduce the manufacturing cost by removing the spacer that was essential in the structure of the conventional condenser microphone.

Third Embodiment

Figure 4 is a third embodiment of the condenser microphone according to the present invention, formed on the surface facing the vibrating membrane 304 in the bipolar plate 308 in a concave surface to deepen toward the center portion of the bipolar plate 308 The vibration membrane 304 is attached to surround the side surface, and the vibration membrane 304 and the bipolar plate 308 are integrally formed. When the diaphragm 304 having an area larger than that of the bipolar plate 308 is attached so that the edge is lowered to the side surface of the bipolar plate 308, the diaphragm / bipolar plate integrated structure is inserted into the case of the condenser microphone. By insulating the bipolar plate and the case, no additional structure is required to insulate the bipolar plate 308 and the case 202.

4, the condenser microphone 300 of the third embodiment according to the present invention includes a metal cylindrical case 302 having a sound hole 302a formed in the front plate and a step 302b for supporting the vibration membrane. The vibrating membrane 304, the ring-shaped first base 306 made of an insulator, and the vibrating membrane 304 are attached to the periphery thereof, and the surface facing the vibrating membrane 304 has a concave surface formed to be deeper toward the center portion. It consists of a bipolar plate 308, a second base 310 made of a conductor, and a PCB 312 on which circuit components are mounted and on which connection terminals are formed. Usually, the components are sequentially stacked in the case 302, and then the case ( Produced by curling the end of 302). At this time, the bipolar plate 308 has a structure in which the polymer film 308b is attached to the metal plate 308a to form an electret, and at the edge of the bipolar plate 308 on which the stepped 302b of the spherical shape is formed. Attaching 304 replaces the Polar Rimg, which was needed to fix the diaphragm in conventional condenser microphones. In FIG. 4, reference numeral 308c denotes a sound hole formed in the bipolar plate 308.

In this third embodiment, one (-) power source of the PCB is applied to the vibrating membrane 304 through the step surface 302b of the case 302, and the other (+) power source is distributed through the second base 310. It is applied to the metal plate 308a of the electrode plate to form a capacitance between the cathode plate 308 and the vibration membrane 304, and the polymer film 308b of the first base 306 and the electrode plate and the polymer film of the vibration membrane The diaphragm 304 and the bipolar plate 308 can keep insulation from each other.

When sound waves are introduced from the outside through the sound holes 302a of the case in such an opposite state, when the vibrating membrane 304 vibrates by the sound waves introduced from the outside, the central portion of the vibrating membrane is largest until the first resonance occurs. It has a displacement, and the displacement becomes smaller toward the edge. In this case, a concave surface similar to the vibration pattern of the vibration membrane is formed on the surface of the bipolar plate 308 facing the vibration membrane 304, so that the displacement of the vibration membrane is converted into an electrical signal.

Therefore, the condenser microphone according to the present invention can improve the sensitivity, and it is possible to reduce the manufacturing cost by removing the spacer that was essential in the structure of the conventional condenser microphone.

As described above, according to the present invention, the polymer film surface of the bipolar plate facing the vibrating membrane is subjected to a series of processing such as pressing a center portion of the bipolar plate to form a concave surface similar to the vibrating shape of the vibrating membrane. Sensitivity can be improved by maximizing the displacement of the film into an electrical signal, and the manufacturing cost can be reduced by eliminating parts by removing a spacer to form an insulation space.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art will be variously modified and changed within the scope of the present invention without departing from the spirit and scope of the invention described in the claims below. I can understand that you can.

Claims (4)

delete delete A metal cylindrical case having a sound hole formed on the front plate and a stepped portion for supporting the vibration membrane; Vibrating membrane made of an insulating polymer film; A bipolar plate in which a vibrating membrane is attached to a peripheral portion and a surface facing the vibrating membrane is formed to have a concave surface so as to deepen toward the center portion; A ring-shaped first base made of an insulator for supporting the bipolar plate; A second base of conductors; And A PCB having a circuit component mounted thereon and a connecting terminal formed thereon; The condenser microphone is characterized in that the diaphragm and the bipolar plate is integrally attached so that the polar ring for supporting the vibrating membrane and the spacer for maintaining the gap between the vibrating membrane and the bipolar plate are removed. delete

Images