KR102673332B1 - Sound receiver filter structure of Mic - Google Patents

Abstract

The present invention is a sound-receiving filter for transmitting sound to the microphone entrance hole of a microphone mounted on an audio device. The sound-receiving filter includes at least one layer forming a sound transmission channel, and the one layer is oriented toward the side of the microphone. It includes a Yinyu entrance opened by .

Description

Sound receiver filter structure of Mic}

The present invention relates to a sound-receiving filter structure of a microphone, an audio device. The filter structure of the present invention is particularly suitable for TWS speakers.

Speakers use the opposite principle of microphones, which convert electrical signals into sound waves. When current enters the coil, the magnet turns into an electromagnet with its own magnetic field and alternately pulls or pushes sound waves in contact with the surrounding continuous magnetic field. It is an electronic product that causes the coil to vibrate due to the force of attraction or repulsion, causing the diaphragm to vibrate, thereby creating sound waves and outputting sound.

Recently, with the development of headsets, especially true wireless speakers (TWS), hybrid wireless premium headsets equipped with a microphone inside the headset and the ability to transmit the user's voice are becoming popular. The user's own voice initially arises from the vibration of the vocal cords. Like bone conduction earphones, this vibration reaches the ear through the auditory cells and inner ear from the vocal cords, and is also transmitted to the ear canal like an external sound through vocalization from the mouth. The microphone captures this vibration as analog sound, and this sound is converted into an electrical signal through an electronic board such as a PCB and finally transmitted to an external device, such as the other person's earphones. The speaker of the other person's earphone converts the electrical signal into an acoustic signal and transmits it to the ear canal.

Patent No. 10-1835353, a patent document related to electronic devices with built-in microphones, discloses a structure in which a microphone is mounted on the opposite side of the sound emitting port of a headset inserted into the user's ears. Patent No. 10-1892263 discloses a structure that removes noise by mounting a small microphone at the rear of the sound emission outlet of the headset housing and preventing the sound from the speaker from being transmitted to the microphone by being blocked by a shielding member.

In Patent No. 10-2287938, the applicant has a structure in which the microphone 10' is mounted in the space of the sound discharge outlet 16' as shown in FIG. 1, specifically, the rear of the microphone 10' is placed on the support of the board, and We proposed a structure mounted vertically so that the front faces the wall of the sound discharge outlet. An upper ring part 110', a ring part 202', and a lower ring part 122' are located in order from the top between the sound radiation surface of the driver and the housing. (12') and (14') are mesh structures.

However, in these prior patents, a hole is formed in the front of the microphone and sound is collected through this hole, so there is a problem that external sounds are mixed in or the space around the microphone must be designed to be wide to secure a sound collection path.

Therefore, the purpose of the present invention is to provide a sound absorption filter that forms a sound transmission path in front of a microphone, and a microphone and sound device equipped with the same.

In order to achieve the above-described object, the present invention is a sound-receiving filter for transmitting sound to the microphone entrance hole of a microphone mounted on an audio device, wherein the sound-receiving filter includes at least one layer forming a sound transmission channel, and the one The layer provides a sound filter, including a sound intake inlet communicating with the outside.

In addition, the present invention is a sound-receiving filter for transmitting sound to the microphone entrance hole of a microphone mounted on an audio device, wherein the sound-receiving filter includes at least two layers forming respective sound transmission channels, and the two layers are : A sound inflow layer including a sound inlet inlet communicating with the outside and an inflow sound transfer groove formed at the end of the sound transfer channel; and, a sound transmission layer comprising a microphone transmission groove communicated with the microphone inlet hole and formed at the end of the sound transmission channel, and an inflow groove communicating with the inflow sound transmission groove.

At the bottom of the sound inflow layer, a first transmission layer having a first groove communicating with the inflow sound transmission groove may be further laminated between the upper surface of the sound transmission layer.

A second transmission layer having a second groove communicating with the microphone transmission groove may be further laminated on the lower part of the sound transmission layer.

The sound transmission channel of the sound inflow layer includes a first channel composed of a plurality of paths continuously connected to communicate between the sound inflow inlet and the incoming sound transmission groove, and the sound transmission channel of the sound transmission layer is between the inflow groove and the microphone inlet hole. It may include a second channel consisting of a plurality of paths continuously connected to communicate.

The first channel includes a first path that communicates with the inlet and extends, a second path that communicates with the outlet of the first path and extends, and the second channel includes a first path that communicates with the inlet groove and extends, and the first path. It communicates with the outlet and may include an extended second path.

Additionally, the present invention provides a sound-absorbing filter manufactured by film lamination, injection molding, or press molding.

The sound absorption filter may further include an outermost cover layer made of adhesive tape for protecting the front of the sound absorption filter or for attaching a microphone.

Additionally, the present invention provides a microphone equipped with the above sound pickup filter.

Additionally, the present invention provides a TWS speaker equipped with the above microphone.

According to the present invention, it is possible to provide optimal sound quality to the microphone by controlling the sound sensitivity through the sound absorption filter of the microphone.

1 is a diagram of a structure equipped with a microphone of the applicant's prior patent;
Figure 2 shows an example of a microphone to which the sound pickup filter of the present invention is applied; Figure 2A is a rear view, Figure 2B is a front view, and Figure 2C is a side view;
Figure 3 is an overall perspective view showing the sound absorption filter applied to the microphone of the present invention;
Figure 4 is a plan view of the negative inflow layer in the structure of Figure 3;
Figure 5 is a plan view of the first transfer layer in the structure of Figure 3;
Figure 6 is a plan view of the sound conduction layer in the structure of Figure 3;
Figure 7 is a plan view of the second transmission layer in the structure of Figure 3;
Figure 8a is a diagram showing the path through which sound is introduced through the sound inflow layer and the first transmission layer in the sound absorption filter of the present invention;
Figure 8b is a diagram showing the path through which sound is transmitted through a microphone through the sound path layer and the second transmission layer in the sound absorption filter of the present invention; and
Figure 9 is a frequency-sound pressure graph before and after applying the sound pickup filter of the present invention to the microphone.

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

Figure 2 shows an example of a microphone 1 to which the sound pickup filter 2 of the present invention is applied. Figure 2a is a rear view, Figure 2b is a front view, and Figure 2c is a side view.

The microphone 1 has a square shape. The rear may be attached to a support not shown or may be open. A microphone entrance hole (1a) through which sound flows is formed on the front. A microphone cover (1b) with a sound-transmitting structure may be located in front of the microphone entrance hole (1a).

The microphone 1 can be modified in various ways, such as being manufactured in a circular shape other than the example shown. In addition, a built-in speaker type such as a TWS is preferable, but the sound-receiving filter 2 of the present invention can be applied to a microphone used in other electronic devices or used alone.

Figure 3 is a diagram showing the sound absorption filter (2) applied to the microphone (1) of the present invention.

The sound-receiving filter (2) has an overall rectangular shape to match the shape of the microphone (1). The sound filter 2 includes a cover layer 20, a sound inflow layer 22, a first transmission layer 24, a sound path layer 26, and a second transmission layer 28 in order from the top. Although the sound-receiving filter 2 has an example of a structure in which five layers are stacked, it is also possible to configure the sound-receiving filter 2 with fewer or more plates.

Hereinafter, each layer of the sound absorption filter 2 of the present invention will be described.

The cover layer 20 is made of adhesive tape to protect the front of the sound-receiving filter 2 or to attach the microphone 1 to the support. Since the sound absorption filter 2 of the present invention is not structured to allow sound to flow in from the front of the cover layer 20, a separate structure for sound absorption is not formed in the cover layer 20.

The sound inflow layer 22 shown in FIG. 4 communicates with a sound inflow inlet 220 and a sound inlet 220 opened in a direction perpendicular to the front of the microphone 1 on one side of the sound inflow layer 22. A first path 222 extends vertically toward the center, communicates with the outlet of the first path 222, and a second path 224 extends horizontally to the right, communicates with the outlet of the second path 224, and connects to the center. A third path 226 extending vertically toward, a fourth path 228 communicating with the outlet of the third path 226 and extending horizontally to the left, and an inflow sound transmission groove formed at the end of the fourth path 228 ( 230) provides a sound inflow channel.

The sound flowing in through the sound inlet 220 sequentially passes through the path and is transmitted to the inflow sound transmission groove 230. The location of the sound inlet 220 is not particularly limited as long as it is formed on the side of the sound inflow layer 22. Since the inflow sound transmission groove 230 is located at the end of a long path, a position opposite to the sound inlet 220 is preferred, but is not particularly limited. The sound inflow channel is in an inverted “ㄷ” shape, but can be formed in a variety of ways, such as an “ㄷ” shape, an “ㄹ” shape, or a zigzag, circular, or bellows shape.

In the first transmission layer 24 shown in FIG. 5, a first groove 240 is formed directly facing and communicating with the incoming sound transmission groove 230. The sound that reaches the incoming sound transmission groove 230 is transmitted through the first groove 240 in a vertical direction, specifically toward the front of the microphone 1.

The sound conduction layer 26 shown in FIG. 6 includes an inflow groove 260 that directly faces and communicates with the first groove 240, and a first path 262 that communicates with the inflow groove 260 and extends in the horizontal direction. ), a second path 264 that communicates with the outlet of the first path 262 and extends vertically upward, a third path 266 that communicates with the outlet of the second path 264 and extends long horizontally, a fourth path 268 that communicates with the outlet of the third path 266 and extends vertically, a fifth path 270 that communicates with the outlet of the fourth path 268 and extends horizontally toward the center, and A sound inflow channel consisting of a microphone delivery groove 272 formed at the end of the fifth path 270 is provided.

The sound flowing in through the first groove 240 and the inflow groove 260 passes through the path in order and is transmitted to the microphone delivery groove 272. Since the microphone delivery groove 272 passes through a long path, a position opposite to the inlet groove 260 is preferred, but is not particularly limited. The sound inflow channel has an overall “ㄴ” symmetrical shape, but can be formed in a variety of ways, such as an “ㄷ” shape, an “ㄹ” shape, or a zigzag, circular, or bellows shape.

In the second transmission layer 28 shown in FIG. 7, a second groove 280 is formed directly facing the microphone transmission groove 272 and communicating with it. The second groove 280 is formed at a position directly opposite the microphone inlet hole 1a in the vertical direction. Accordingly, the sound that has passed through the microphone transmission groove 272 and the second groove 280 is transmitted to the microphone 1 through the microphone entrance hole 1a without changing the direction of travel.

Figure 8a is a diagram showing the path through which sound is introduced through the sound inflow layer 22 and the first transmission layer 24 in the sound absorption filter 2 of the present invention described above.

Figure 8b shows that the sound inflow layer 22 and the first transmission layer 24 are removed from the sound receiving filter 2 of the present invention described above, and the microphone 1 is removed through the sound path layer 26 and the second transmission layer 28. ) is a diagram showing the path through which sound is transmitted.

Through these two drawings, the sound transmission path of the present invention can be clearly understood.

Figure 9 is a frequency-sound pressure graph before and after applying the sound absorption filter (2) to the microphone (1) of the present invention. It can be seen that when the sound absorption filter (2) is applied, the sound pressure increases in the low frequency range below 300Hz, and the sound pressure becomes lower in the frequency range above that. Since the surrounding members and noise environment surrounding the microphone (1) are diverse, optimal sound can be achieved by changing the noise filter (2).

The sound absorption filter 2 of the present invention is generally formed of a film layer other than a tape. However, parts other than the tape material can be made of plastic by injection molding or press molding.

Various changes are possible to the sound absorption filter 2 of the present invention. One or both of the first transmission layer 24 and the second transmission layer 28 can be removed and the sound inflow layer 22 and the sound transmission layer 26 can be directly connected. A single-layer structure in which only the sound inflow layer 22 is left and the incoming sound transmission groove 230 directly communicates with the microphone inlet hole 1a is also possible. When implemented in one or two layers, the sound absorption filter (2) can be manufactured as a whole by injection molding. On the contrary, the sound inflow layer 22 can have a two-layer structure to expand the sound inlet inlet 220, or it can be formed with six or more layers by further stacking layers that provide a sound transmission path.

In addition, the sound channels of the sound inflow layer 22 and the sound transmission layer 26 are only examples and can be changed in various ways as long as they provide a sound propagation path.

Although the preferred embodiments of the present invention have been described above, it is obvious that various changes and modifications can be made to the present invention and that the scope of rights of the present invention extends to the same or equivalent area as the claims described below.

Claims (10)

delete A sound absorbing filter for transmitting sound to the microphone entrance hole of a microphone mounted on an audio device,
The sound absorption filter includes at least three layers forming respective sound transmission channels, the three layers being:
A sound inflow layer including a sound inlet inlet communicating with the outside and an inflow sound transfer groove formed at the end of the sound transfer channel;
a sound transmission layer including a microphone transmission groove communicating with the microphone inlet hole and formed at the end of the sound transmission channel, and an inflow groove communicating with the inflow sound transmission groove; and
It consists of a second transmission layer with a second groove communicating with the microphone transmission groove at the bottom of the sound transmission layer.
The sound absorption filter further includes an outermost cover layer made of adhesive tape for protecting the front of the sound absorption filter or for attaching a microphone,
The sound inlet is formed in a direction perpendicular to the front of the microphone, so that external sound flows in through direct communication with the entrance of the incoming sound transmission groove of the sound inflow layer and passes through the entire path of the incoming sound transmission groove.
Compared to before installing the sound absorption filter, the sound pressure is higher in a certain low frequency range, and the sound pressure is lower in the frequency range above that. According to clause 2,
A sound absorption filter in which a first transmission layer having a first groove communicating with the inflow sound transmission groove is further laminated on the lower part of the sound inflow layer and the upper surface of the sound transmission layer. delete According to clause 2,
The sound transmission channel of the sound inflow layer includes a first channel composed of a plurality of paths continuously connected to communicate between the sound oil inlet and the inflow sound transmission groove,
The sound transmission channel of the sound transmission layer includes a second channel composed of a plurality of paths continuously connected to communicate between the inflow groove and the microphone inlet hole. According to clause 5,
The first channel includes a first path that communicates with and extends from the sound milk inlet, and a second path that communicates with and extends from the outlet of the first path,
The second channel is
A water-receiving filter comprising a first path extending and communicating with the inlet groove, and a second path extending and communicating with the outlet of the first path. According to clause 2,
The sound-absorbing filter is manufactured by film lamination, injection molding, or press molding. delete A microphone equipped with the sound-receiving filter of paragraph 2. TWS speaker equipped with the microphone of Clause 9.