KR101181669B1 - Optical microphone - Google Patents

Abstract

PURPOSE: An optical microphone is provided to precisely sense vibration by stably fixing an optical fiber which senses vibration. CONSTITUTION: One side of a hollow housing(100) is opened. A fixing unit(200) has a frame of a ring shape. A vibration plate vibrating with external sound is attached to the opened one side of the frame. A jig(300) has a body which is fixed while being inserted into the frame of the fixing unit and keeping a space with the vibration plate. A pair of inserting holes is formed in the jig body. A pair of optical fibers is respectively received to the inserting hole of the jig.

Description

Optical microphone

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to optical microphones, and more particularly, to an optical microphone that can accurately sense vibrations by stably fixing an optical fiber for sensing vibrations.

Sound is an important physical phenomenon related to the quality of life for modern people, and research on sensors and methods to measure it is very important.

In terms of sound, the microphone is the most basic and necessary conversion sensor, and it is very important.

The research and development of microphones has been continued since the study of acoustics, and the kinds are difficult to understand, but there are dynamic microphones and condenser types.

Dynamic microphone has a long history as a transducer that converts mechanical vibration into an electrical signal by electromagnetic conversion, and is structurally strong and strong against external shocks. However, it has a problem that it is difficult to miniaturize because it is greatly affected by the surrounding electromagnetic waves.

The condenser microphone is known to have the best performance among the microphones developed to date, and it applies a polarization voltage between two adjacent charging plates and measures the sound pressure signal by the generation of electric charge due to the change of distance of the charging plate which vibrates by sound pressure. Because of its excellent frequency and good signal-to-noise ratio, it is widely used as a measurement microphone.

However, in order to improve the sensitivity, the vibrating charging plate should be widened, the distance between them should be small, and the polarization voltage should be increased.

Because of this, it is very vulnerable to changes in the external environment such as moisture, and it is not easy to manufacture with the disadvantage that it is difficult to handle.

Therefore, electret microphones have been developed that use electric polymer films that are already charged instead of polarization voltage to supplement them and use them for general devices.

Electret microphones are used today in most common devices because they are relatively simple to manufacture, inexpensive, compact, and perform well.

However, this type of microphone is basically a vibrating plate is a polymer of polymer material, the vibration characteristics are not as good as metal and still have disadvantages such as area and moisture of the conventional condenser microphone.

In order to overcome the shortcomings of the existing microphone, an optical microphone has been developed and used in recent years, and FIG. 1 is a diagram illustrating a structure of a general optical microphone.

As shown in FIG. 1, a pair of optical fibers 120 and 130 are introduced into the housing 100 of a cylindrical body having one surface open, and the ends of the optical fibers 120 and 130 are installed with a fixed reflection angle.

On the outside of the housing 100, the light source 150 and the light detector 160 are coupled to the other ends of the optical fibers 120 and 130, respectively, such a light source 150 may be composed of an optical laser or a light emitting diode, 160 may use a photodiode.

Accordingly, the end of the optical fiber 120 fixed by the fixing unit 110, that is, the light output unit 121, emits light generated from the light source 150 through the diaphragm 140. The light is reflected, and the reflected light is introduced through the light inlet 131 so that the light detector 160 receives the light.

The optical path of the reflected light changes according to the vertical displacement of the diaphragm 140 reflecting the light. As shown in FIG. 2, the light output part 121 and the light inlet part 131, which are the ends of the two optical fibers 120 and 130, are centered. It has a constant angle (θ) from the axis, respectively installed in close proximity to the diaphragm 140, when the diaphragm 140 is displaced up and down by an external sound, the reflection angle of the light is changed, thereby increasing the intensity of the light entering the light detecting unit 160 Is changed.

As a result, the flow of electric current, which is an electrical signal converted by the photodetector 160, is changed to change the magnitude of the electrical signal according to the external sound.

However, in the conventional optical microphone, since the light output part 121 and the light entrance part 131 are exposed to the outside of the fixing part 110, there is no structure for fixing the light output part 121 by an external impact. ) And the light inlet 131 are easily shaken, so that the vibration of the diaphragm 140 cannot be correctly sensed.

This prevents the vibration from being correctly converted into an electrical signal, which has a problem of deterioration of performance.

The present invention is to solve the problem of the conventional optical microphone to improve the performance of the microphone by adding a jig for fixing with an accurate angle to the end of the optical fiber, and a structure for effectively transmitting the vibration generated by the diaphragm The purpose is to provide.

Optical microphone according to an embodiment of the present invention for achieving the above object,

A cylindrical housing having one side open;

The surface has a ring-shaped frame formed of plasma-treated PDMS (Polydimethyl-siloxane), a diaphragm vibrating by external sound is attached to an open side of the frame, and the other side of the frame is connected to an open end of the housing. A fixed portion coupled;

The fixing part has a body which is inserted into the frame and is fixed while maintaining a space with the diaphragm, the body has a pair of insertion holes to be inserted and fixed with a pair of optical fibers having a constant reflection angle with respect to the diaphragm Jig formed;

A pair of optical fibers respectively accommodated in the insertion holes of the jig, the ends of which are received so as not to be exposed to the outside of the jig, and the other side thereof is drawn out of the housing so that the light source and the light detector are coupled to the other end thereof, respectively. do.

According to the present invention, since a pair of optical fibers for transmitting the light for detecting the vibration of the diaphragm is stably fixed by the jig, it is possible to increase the reliability by preventing the optical signal transmission error due to external impact.

In addition, by forming a frame for fixing the diaphragm with PDMS, the diaphragm can effectively cause vibration, which also has the advantage of preventing reliability of optical signal transmission and improving reliability.

1 is a view showing the structure of a general optical microphone.
2 is a diagram for explaining the principle of an optical microphone.
Figure 3 is a view showing a fixing structure of the diaphragm and the optical fiber applied to the present invention.
Figure 4 is a view showing the structure of an optical microphone according to an embodiment of the present invention.
Figure 5 shows the structure of an optical microphone according to another embodiment of the present invention.

The present invention configured as described above will be described in detail with reference to the accompanying drawings.

Figure 3 is a view showing a cross-sectional structure of the fixing part 200 and the jig 300, which is the main part of the present invention, the fixing part 200 is composed of a frame 210 in the form of a square or circular ring, the opening The diaphragm 220 is attached to cover all the open portions at the top.

At this time, the frame 210 is formed using a flexible and elastic material of PDMS (Polydimethyl-siloxane), so that the diaphragm 220 to efficiently transmit vibration, such PDMS has an insulation, less affected by the magnetic field Does not distort vibration

In addition, since the thermal conductivity is low and does not deform even at high temperatures, it can also be transmitted faithfully without distorting vibration.

The PDMS has a Young's modulus value of 360 to 870 Kpa, which is a modulus of elasticity, which is 8 to 30 times larger than a silicone rubber having a Young's modulus value of 10 to 100 Kpa, thereby effectively transmitting vibration.

In addition, the PDMS has a thermal conductivity of 0.15 W / mK, which is significantly lower than that of metal, and thus does not cause deformation due to heat, thereby stably fixing the diaphragm 220 so that vibration is faithfully transmitted through the diaphragm 220. .

In addition, since the resistivity is 4 × 10 ¹³ Ωm, the insulation is very excellent and is not influenced by electricity, so that the vibration is faithfully transmitted.

Due to this, the vibration of the diaphragm 220 is made by reflecting this even by a fine external sound, thereby making the sensing sensitivity excellent.

The diaphragm 220 has cost-effectiveness by using a high reflectivity sheet such as a synthetic resin material or a metal (gold, silver, aluminum, copper, nickel, etc.) that can be easily obtained.

The jig 300 forms a body 310 made of a hard material of plastic or metal, and the body 310 is inserted into and fixed inward from the bottom of the frame 210 of the fixing part 200, and the body 310. A space 400 having a distance of about 5 μm to about 10 μm is formed between the top of the bottom and the bottom surface of the diaphragm 220 as shown in FIG. 4.

In order to fix the jig 300 inside the fixing part 300, various fixing means such as forced indentation and an adhesive may be used.

The body 310 is provided with insertion holes 320 and 330 having an inverted 'V' shape inclined upwardly so that a pair of optical fibers 120 and 130 may be inserted, respectively, and upper ends of the insertion holes 320 and 330 are spaced apart from each other. It is desirable to have an inclination such that the imaginary extension lines of the insertion holes 320 and 330 meet at the lower surface of the diaphragm 220.

Therefore, the optical fiber 120 for light output and the optical fiber 130 for light incident are inserted into and inserted into the insertion holes 320 and 330, respectively, wherein the ends of the optical fiber 120 and 130 are outside the upper side of the body 310. It is not exposed and is located close to the upper end inside the insertion holes 320 and 330.

This is to prevent the case that the end of the optical fiber (120,130) is not shaken by the external shock to faithfully detect the transmission of vibration, and the inner diameter of the insertion hole (320,330) is the optical fiber (120,130) to prevent the optical fiber (120,130) from shaking. It is the same as or slightly larger than the outer diameter of the) to be fixed without shaking in the insertion holes (320,330).

The fixed part 200 and the jig 300 coupled as described above are coupled to an open upper side of the housing 100, and the lower end of the frame 210 of the fixed part 200 is placed on the upper end of the housing 100 by an adhesive or the like. It is fixed.

The other sides of the optical fibers 120 and 130 are drawn out to the outside of the housing 100 so that the light source 150 and the light detector 160 are coupled to the ends thereof to detect the intensity of the light due to the vibration of the diaphragm 220.

In the present invention, the wavelength of the light generated from the light source 150 has a length of 1550 nm, and the amplitude of the diaphragm 220 is set to about 50 μm.

5 is a view showing another embodiment of the present invention, the structure of the housing 100, the frame 210 and the diaphragm 220 is the same as in the embodiment of the present invention, the inside of the housing 100 The light guide port 500 is mounted.

The light guide hole 500 has a guide hole 510 is formed in the vertical direction, the guide hole 510 has a form in which the inner diameter is diffused toward the upper side, which is the light of the displacement according to the displacement of the diaphragm 200 This is to induce light into the induction hole 510 even if the reflection angle is changed.

One end of the optical fiber 140 is inserted below the induction hole 510, and the optical fiber 140 is in a single mode and is responsible for the light incident and exiting the light into the light guide hole 500.

The other end of the optical fiber 140 configured as such a single mode is connected to an optical circulator 600, and light is incident and emitted by polarization of the optical circulator 600. 600 uses a planar polarization prism to inject light generated from the light source 150 into the light guide hole 500 through the optical fiber 140, and to emit light emitted from the light guide hole 500. It serves to deliver to the light detector 160.

Therefore, the light generated from the light source 150 is transmitted to the optical fiber 140 through the optical circulator 600 is irradiated to the diaphragm 220 through the induction hole 510 of the light guide hole 500, the diaphragm ( The light reflected from the 220 is incident to the optical fiber 140 through the induction hole 510 and exits to the light detector 160 through the optical circulator 600.

100: housing 120130: optical fiber
150: light source 160: light detector
200: fixing portion 210: frame
220: diaphragm 300: jig
310: body 320,330: insertion hole
500: light guide hole 510: guide hole
600: optical circulator

Claims (5)

A cylindrical housing having one side open;
A fixing part having a ring-shaped frame, and having a diaphragm vibrated by an external sound on an open side of the frame, the other side of the frame being coupled to an open end of the housing;
The fixing part has a body which is inserted into the frame and is fixed while maintaining a space with the diaphragm, the body has a pair of insertion holes to be inserted and fixed with a pair of optical fibers having a constant reflection angle with respect to the diaphragm Jig formed;
A pair of optical fibers respectively accommodated in the insertion holes of the jig, the ends of which are received so as not to be exposed to the outside of the jig, and the other side thereof is drawn out of the housing so that the light source and the light detector are coupled to the other end thereof, respectively. Optical microphone, characterized in that.
The optical microphone according to claim 1, wherein the frame of the fixing part is made of polydimethyl-siloxane (PDMS) whose surface is plasma-treated.
The optical microphone according to claim 1, wherein the diaphragm is a thin plate made of synthetic resin or metal.
A cylindrical housing having one side open;
A diaphragm attached to an open portion of the housing and vibrating by an external sound;
A light guide hole inserted into the housing to be fixed while maintaining a space with the diaphragm and having a guide hole formed to penetrate the vertical direction;
An optical fiber having one end inserted into a lower side of the guide hole of the light guide hole;
An optical circulator connected to the other end of the optical fiber;
A light source for injecting light into the optical circulator;
And an optical detector for detecting light emitted from the optical circulator.
The optical microphone according to claim 4, wherein the guide hole of the light guide port is configured such that its inner diameter is diffused toward the upper side.

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