KR200156511Y1 - A structure for mounting a microphone to a monitor - Google Patents

Abstract

The present invention relates to a microphone mounting structure of the monitor, in order to receive a sound signal of the two-way sound-sensitive microphone, the sounding plate is sufficiently vibrated, the receiving portion 4 is formed in the front inside the microphone 2 is formed, The space portion communicating with the receiving portion 4 inside the rear side and communicating with the outside through the intake hole 6 formed in the rear lower side wall portion and the outlet hole 5 of the electric wire 1 formed in the rear side wall portion. An anti-vibration member (8) formed with an anti-vibration member (10) and an anti-vibration member (10) formed in the inner wall portion of the monitor enclosure (3) and the receiving space (9) formed so that the anti-vibration member (8) is fitted. ), The audio performance of the microphone is improved as much as possible.

Description

Microphone mounting structure of the monitor

The present invention relates to a microphone mounting structure of a monitor. In particular, when a two-way sound sensing microphone is mounted on the monitor main body, the microphone mounting of the monitor can be improved to improve the audio performance of the microphone as much as possible. It's about structure.

In general, a microphone is a device that first converts the signal energy of an acoustic system into mechanical signal energy, and finally converts the converted mechanical signal energy into signal energy of an electric system.

Here, the operation of the microphone converting the acoustic signal energy into mechanical signal energy is performed through a sound board built into the microphone itself, and the type and characteristics of the microphone are determined according to the direction in which the sound board detects external sound. do.

In other words, the omnidirectional sound sensing microphone configured to detect sound coming from all around the microphone is suitable for accepting a short-range outgoing sound, while a bidirectional sound sensor configured to detect only sound coming into the front and back of the microphone. Terrain microphones can accept relatively long distance dialing, providing greater sensitivity and better audio performance than omnidirectional sound-sensing microphones.

On the other hand, when the microphone is mounted in such an electronic product, the vibration is transmitted to the electronic product due to the characteristics of the microphone itself, that is, the sounding plate of the microphone causes mechanical vibration by the input sound signal. It is necessary to avoid adverse effects

In particular, when the microphone is to be mounted on an electronic product such as a monitor, a slight vibration generated by the microphone may be transmitted to the receiving pipe as it is, which may cause a problem that the monitor screen is shaken. It is wrapped by an anti-vibration member having a rubber material and mounted on the monitor enclosure.

For example, in FIG. 3, the state in which the microphone 50 is surrounded by the vibration preventing member 51 and mounted on the monitor enclosure 52 is illustrated, and the hole in the front portion of the microphone 50 is exposed. A rib is formed in the inner wall portion of the monitor enclosure 52 in which a hollow part is formed in the inner side so as to surround the body of the microphone 50 while the 53 is perforated. The state sandwiched between the 54 is shown.

Here, when the microphone is an omnidirectional sound-sensing microphone, the microphone has a characteristic, that is, a characteristic that can detect the dial tone in any direction from which the microphone is mounted. Even when the microphone is mounted by the mounting structure as described above, the microphone can sufficiently detect an external transmission sound through a hole formed in front of the vibration preventing member.

However, in the case where the microphone is a bidirectional sound sensing microphone, the microphone is capable of performing properly only when the microphone detects a sound from outside from the front and rear of the microphone at the same time. As described above, there is a problem that the performance of the microphone may not be sufficiently exhibited because it is mounted by a structure capable of receiving only a dial tone from the front.

Therefore, the present invention was devised to solve the above problems, and when the two-way sound sensing microphone is mounted in the monitor enclosure, the microphone can detect the incoming sound from the outside sufficiently to maximize the audio performance of the microphone itself. The purpose is to provide a microphone mounting structure for a monitor.

In order to achieve the above object, the present invention has a structure in which a microphone is soldered and connected to a rear side of an electric wire in a monitor enclosure, and a receiving portion into which the microphone is fitted is formed in a front inner side, and the receiving portion and a rear inner side thereof. A vibration preventing member having a space portion communicating with the outside through the wire lead-out hole formed in the rear side wall portion and an inflow hole formed in the rear lower wall portion, and formed in the inner wall portion of the monitor enclosure. Consists of the vibration-proof member accommodating portion is formed so that the receiving space.

Therefore, according to the above-described technical configuration, since both front and rear of the microphone are open to the outside, and a dial tone from the outside can enter the front and back of the microphone at the same time, when the microphone is mounted as a bidirectional sound sensing microphone, the microphone Its own audio performance has the greatest advantage.

1 is a perspective view showing a microphone mounting structure according to the present invention,

2 is a cross-sectional view showing a state in which a microphone is mounted according to the present invention,

3 is a cross-sectional view showing a microphone mounting structure according to the prior art configuration.

Explanation of symbols on the main parts of the drawings

1-wire 2-microphone

3-monitor enclosure 4-receptor

5-outlet 6-inlet

7-space 8-vibration prevention member

9-Accommodating space 10-Vibration preventing member

11-through hole 12-through hole

13-hole

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

Figure 1 shows a perspective view of the microphone mounting structure according to the present invention, Figure 2 is a cross-sectional view of the assembly structure of the microphone mounting structure according to the present invention, the mounting structure according to the present invention, the wire (1) in the rear In the structure in which the soldered microphone 2 is mounted on the monitor enclosure 3, an accommodating portion 4 into which the microphone 2 is fitted is formed in the front inner side, and the accommodating portion 4 in the rear inner side. And a vibration preventing member having a space portion 7 communicating with the outside through the withdrawal hole 5 of the wire 1 formed in the rear side wall portion and the inflow hole 6 formed in the rear lower side wall portion. 8) and an anti-vibration member accommodating part 10 formed in the inner wall of the monitor enclosure 3 and in which the receiving space 9 is formed so that the anti-vibration member 8 is fitted.

Here, the anti-vibration member accommodating portion 10 is formed on the inner wall portion of the monitor enclosure (3) is formed of a rib (rib) surrounding the anti-vibration member (8), the lower side of the rib ( A communication hole 11 is formed in 10a so as to communicate with the inflow hole 6 of the vibration preventing member 8, and the communication hole 11 is again a through hole formed in the side wall portion of the monitor enclosure 3. Communicate with (12) again.

The space portion 7 formed on the front side of the vibration preventing member 8 communicates with the hole 13 formed in the front side wall portion of the monitor enclosure 3.

On the other hand, when the dial tone is introduced into the space portion 7 from the outside through the through hole 12 in the lower rear corner of the vibration preventing member 8, the dial tone is not distributed to the inside of the monitor enclosure (3). The guide plate 14 protrudes so as to give an inflow path of the dial tone, and the tip of the guide plate 14 is in contact with the inner wall portion 3a of the monitor enclosure 3.

When the microphone 2 is mounted in the structure configured as described above, as shown in FIG. 2, a path through which an external dial tone is introduced to the front and rear of the microphone 2 is formed, that is, the microphone ( The front of 2) is exposed to the outside through the opening of the monitor enclosure 3, whereby an inflow path for external dial tone from the front of the microphone 2 is formed, while the rear of the microphone 2 is provided with the space 7 By communicating with the outside through the inflow hole 6, the communication hole 11, and the through hole 12, the inflow path of the external dial tone from behind the microphone 2 is formed.

Therefore, according to the above-described technical configuration, since the front and rear of the microphone 2 are all open to the outside, and a dial tone from the outside can simultaneously enter the front and rear surfaces of the microphone 2, the microphone 2 is a bidirectional sound sensing microphone ( 2), the audio performance of the microphone 2 itself is improved as much as possible.

According to the microphone mounting structure of the monitor according to the present invention described above, when the two-way sound-sensing microphone is mounted in the monitor enclosure, the microphone can detect the incoming sound from the outside enough to improve the audio performance of the microphone itself as much as possible It works.

Claims (2)

In the structure in which the electric wire 1 is attached to the monitor enclosure 3 with the microphone 2 soldered to the rear side, a receiving portion 4 into which the microphone 2 is fitted is formed in the front inner side, and in the rear inner side. A space portion 7 which communicates with the receiving portion 4 and communicates with the outside through an inlet hole 6 formed in the rear lower side wall portion and an outlet hole 5 of the wire 1 formed in the rear side wall portion. A vibration preventing member 8 formed with an anti-vibration member 8 and a vibration preventing member accommodating part 10 formed at an inner wall of the monitor enclosure 3 so that the vibration preventing member 8 is fitted therein. In the lower side of the accommodation space (9), the communication hole (11) and the through hole (12) are formed in a line so that the space portion (7) communicates with the outside, while the front of the accommodation space (9) The microphone of the monitor, characterized in that the hole 13 is formed on the side so that the receiving portion 4 communicates with the outside. Von mounting structure. 2. The monitor enclosure (3) according to claim 1, wherein the front lower edge of the vibration preventing member (8) has a front end portion such that a dial tone is introduced into the space portion (7) from the outside through the through hole (12). The microphone mounting structure of the monitor, characterized in that the guide plate 14 is formed in contact with the inner wall portion (3a) of the.