KR101471614B1 - Method and apparatus for blocking noise - Google Patents

Abstract

A method and an apparatus for blocking noise are disclosed. A headphone for blocking noise includes a noise reduction unit and an ear cap. The band-shaped noise reduction unit has both ends to be connected with the ear cap. The cap-shaped ear cap has an inner space formed therein so that ears of a user of the headphone for blocking noise is positioned, and covers the ears. The noise reduction unit partially has a cross-section with a polygonal porous structure. The inside of the porous structure is in a vacuum. The noise reduction unit includes a communication unit. The communication unit receives a signal transmitted from the outside. The ear cap includes an output device. The output device can output the signal. Therefore, the method and the apparatus for blocking noise can prevent buzzing caused by noise by increasing a noise blocking rate.

Description

METHOD AND APPARATUS FOR BLOCKING NOISE [0002]

The present invention relates to a headphone, and more particularly, to a headphone that shields noise.

Tinnitus refers to a symptom in which sounds are heard in the ear even if the surroundings are quiet. Tinnitus can be caused by various causes such as nutritional imbalance or complications. Most of the tinnitus symptoms disappear naturally when the cause of the noise disappears. However, if the tinnitus is damaged due to exposure to loud noises, it can not be treated and it can cause a lifelong ejaculation.

Shooting noises encountered by adult men during military service are 140dB (decibel) when shooting rifles and 160dB when shooting shells. This shot noise has a much larger dB than the sound when the plane takes off. In fact, after the shooting training, many soldiers experience symptoms that can not be heard for a few days. A soldier after a shooting training with a tinnitus is said to have heard a few days or so in a short time, though hearing may return within a few days. In addition to the soldiers exposed to the shooting noise, other large noises also have the characteristic that they can not hear the sound of high-frequency sound, and most of them are accompanied by tinnitus symptoms.

Tinnitus symptoms, even if you go to the hospital, there is no special treatment yet. Tinnitus does not return to normal within one to two months after the onset of the disease, and when he is chronic, hearing loss is worse and hearing is worse, and many years later, he finds out that shooting noise caused tinnitus or hearing loss . Tinnitus or hearing loss victims can be disadvantaged in employment. In addition, it is often difficult to maintain normal working life after employment, and serious illnesses can also occur.

The number of people who have suffered from tinnitus or hearing loss during military service is estimated to be about 33,000. The Department of Defense has obligated the soldiers to wear earplugs to prevent noise when they are exposed to noise since 1991. The problem is that it is not easy to wear an earplug to prevent noise from the field. The reason is that the risk of accidents is high because you can not hear the surrounding sounds when you put on earplugs.

However, since damaged hearing nerves are not restored or treated, prevention is the most important and it is necessary to prevent the hearing impairment from progressing further by protecting it at the stage of hearing loss.

It is an object of the present invention to provide a noise shielding method.

Still another object of the present invention is to provide an apparatus for performing a noise shielding method.

According to another aspect of the present invention, there is provided a noise shielding headphone including a noise attenuator and an ear cap, wherein the noise attenuator is band-shaped and the ear cap is connected to both ends of the ear cap. And the ear cap may be formed in a cap shape having an inner space in which an ear of a wearer of a headphone is shielded to shield the ear while the noise attenuating part has a polygonal cross- Wherein the interior of the porous structure is in a vacuum state, the noise attenuating part includes a communication part, the communication part receives an externally transmitted signal, the ear cap includes an output device, and the output device And can output the signal. The polygonal shape may be a hexagonal shape. The polygonal porous structure may be realized by including a plurality of pipes inside the noise attenuating unit. The noise attenuator may be configured to surround the wearer's neck wearing the noise-shielding headphone. The noise attenuator may be configured to surround the burgundy of the wearer wearing the noise-shielding headphone. The ear cap may be formed in a shape in which a thickness of a portion shielding the upper end of the ear is thinner than a thickness of a portion shielding the lower end of the ear. Wherein a portion shielding the upper end of the ear is made of a material having elasticity, and when a wearer wearing the noise-shielding headphone wears a burgundy on the basis of the elasticity, As shown in FIG. The noise cancellation headphone may further include a noise cancellation signal determiner and a noise cancellation signal generator, wherein the noise cancellation signal determiner is configured to generate a noise cancellation signal based on the modeled noise pattern, May be implemented to output the noise cancellation signal determined by the noise cancellation signal determiner through the output device, wherein the noise cancellation signal may be an anti-phase signal of the modeled noise pattern. The noise shielding headphone may further include a noise information receiving unit and a noise pattern modeling unit. The noise information receiving unit may be configured to receive sound information from a noise source. The noise pattern modeling unit may be configured to receive the sound information May be implemented. The noise source may be a military equipment. The output device may be a speaker or a bone conduction earphone. The noise attenuator may additionally include a suction member in a strip shape in a part thereof. The noise shielding headphone may further include a voice receiving unit, and the voice receiving unit may be configured to receive a voice signal of a wearer of the noise shielding headphone. The length adjuster may be configured to adjust the length of the band according to the individual body characteristics of the wearer of the noise shielding headphone, and the length adjuster may be implemented as a wearable material .

According to another aspect of the present invention, there is provided a method for generating noise cancellation signals of a headphone for noise shielding, the method comprising: receiving modeled noise pattern information; Determining the cancellation signal, and outputting the noise cancellation signal determined by the determined noise cancellation signal determiner, wherein the noise cancellation signal may be an anti-phase signal of the modeled noise pattern. The noise cancellation signal generating method may further include receiving sound information from a noise source and modeling characteristics of the sound information based on sound information of the noise source, wherein the noise source may be a combat device.

As described above, the noise shielding method and apparatus according to the embodiment of the present invention can increase the noise shielding rate and prevent tinnitus due to noise.

1 is a conceptual view showing a headphone for noise shielding according to an embodiment of the present invention.
2 is a conceptual view showing a cross section of a sound attenuator according to an embodiment of the present invention.
3 is a conceptual view showing a section of a noise attenuator according to an embodiment of the present invention.
4 is a conceptual diagram illustrating a noise attenuator of a headphone for noise shielding according to an embodiment of the present invention.
5 is a conceptual diagram illustrating a noise attenuator of a headphone for noise shielding according to an embodiment of the present invention.
6 is a conceptual diagram illustrating a signal receiving unit of a noise attenuator according to an embodiment of the present invention.
7 is a conceptual diagram illustrating a signal transmitter of a noise attenuator according to an embodiment of the present invention.
8 is a conceptual diagram illustrating an ear cap according to an embodiment of the present invention.
9 is a conceptual diagram illustrating a noise cancellation signal generating method according to an embodiment of the present invention.
10 is a conceptual view showing a headphone for shielding noise according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present disclosure rather unclear.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . In addition, the description of "including" a specific configuration in the present invention does not exclude a configuration other than the configuration, and means that additional configurations can be included in the practice of the present invention or the technical scope of the present invention.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

In addition, the components shown in the embodiments of the present invention are shown independently to represent different characteristic functions, which does not mean that each component is composed of separate hardware or software constituent units. That is, each constituent unit is included in each constituent unit for convenience of explanation, and at least two constituent units of the constituent units may be combined to form one constituent unit, or one constituent unit may be divided into a plurality of constituent units to perform a function. The integrated embodiments and separate embodiments of the components are also included within the scope of the present invention, unless they depart from the essence of the present invention.

In addition, some of the components are not essential components to perform essential functions in the present invention, but may be optional components only to improve performance. The present invention can be implemented only with components essential for realizing the essence of the present invention, except for the components used for the performance improvement, and can be implemented by only including the essential components except the optional components used for performance improvement Are also included in the scope of the present invention.

Hereinafter, an embodiment of the present invention will be described with respect to a method for shielding a shooting sound generated when a shooter performs shooting based on a noise-shielding headphone for the sake of explanation. However, the noise-shielding headphones disclosed in the embodiment of the present invention may be used for other purposes for shielding noise, for example, in a place where noises such as a construction site and a dental are generated, Examples are also included in the scope of the present invention.

1 is a conceptual view showing a headphone for noise shielding according to an embodiment of the present invention.

Referring to FIG. 1, the headphone for shielding noise may include a noise attenuator 100 and an ear cap 140 connected to both ends of the noise attenuator 100.

The sound attenuation unit 100 may have a structure including elastic space and a void space therein. The sound attenuation unit 100 may be embodied with a certain elasticity and curved shape according to the shape of the head of the shooter. The noise attenuator 100 may be implemented to perform the role of a band for fixing the ear cap 140 to the shooter in the noise shielded headphone. The internal space of the sound attenuation unit 100 may include a structure for sound absorption and absorption. The interior of the noise attenuation unit 100 may include a signal receiving unit for receiving an external signal and transmitting the received signal to the shooter. The external signal may be, for example, a command from the commander to cause the shooter to perform and stop shooting, or may be information about a noise cancellation signal to be generated by the noise-shielded headphone.

The portion of the sound attenuation unit 100 which can be in contact with the head of the shooter may additionally have a cushion structure. Vibration can be prevented from being directly transmitted from the noise attenuator 100 to the head of the shooter through the cushion structure. The internal space structure for performing the sound absorption of the sound attenuation unit 100 will be further described in detail. The length adjuster 120 may be disposed between the noise attenuator 100 and the ear cap 140 to adjust the length depending on the shape of the head of the shooter and the position of the ear. Based on the length adjuster 120, the shooter is brought into close contact with the head, neck or bumpy part of the noise attenuator 100, so that the noise-shielded headphone can be worn securely.

Noise shielding headphones can be used for shooting training. In this case, the structure of the noise attenuator 100 may be designed to be worn above the helmet such as a bulletproof broom, considering the structure of the broomstick. As another example, the sound attenuating unit 100 may be disposed on the neck of the shooter behind the bullet of the shooter. The detailed structure of the noise attenuator 100 will be described later.

The cap 140 may be connected to both ends of the noise attenuator 100 to provide a shielding structure for the external ear. The cap 140 and the sound attenuator 100 may be realized in such a structure that the two components are detachable, so that one of the components can be replaced when the component becomes old. The headphone for noise shielding according to the embodiment of the present invention may include a speaker in the ear cap 140 to transmit a signal such as a voice signal received from the signal receiver to the shooter. According to the embodiment of the present invention, it is also possible that the signal receiving unit is not included in the sound attenuating unit 100 and the signal receiving unit is included in the ear cap 140. In this case, the sound attenuating unit 100 may include a sound absorbing / As a band of a headphone.

In one exemplary embodiment of the noise-shielded headphone, the signal received by the signal receiver of the sound attenuator 100 may be transmitted to the speaker of the ear cap 140 via wire or wireless. When a signal received by the signal receiving unit is transmitted to the speaker of the ear cap 140, the signal receiving unit of the sound attenuator 100 and the speaker of the ear cap may be electrically connected to each other based on the wire . In this case, the ear cap 140 and the noise attenuator 100 may be connected to each other in such a manner that they are not detachable.

When a signal is transmitted and received between the sound attenuator 100 and the ear cap 140 based on radio waves, a radio signal transmitted through the signal receiver of the sound attenuator 100 is transmitted to a communication unit And the cap 140 can output the received signal through the speaker.

It is possible to embody a battery in a noise shielding headphone or to generate electric energy based on another energy source so that an electric operation is performed in a noise shielding headphone.

The cap 140 may include a cushion and may have a closed structure for blocking external noise. The ear cushion included in the cap 140 may be formed of a material that can be brought into close contact with the skin around the outer surface of the puncture person. The ear cushion of the ear cap 140 can be brought into close contact with the skin around the outer periphery of the shooter based on the elasticity and length adjuster 140 of the noise attenuator 100. [ In addition, when the skin of the user is brought into close contact with the skin around the outer ear, the air inside the cap 140 can be partially escaped based on the elasticity of the ear cushion. In this case, the inside of the ear cushion may be in a partial vacuum state, and in this way, the adhesion between the skin around the ear and the ear cushion can be increased.

In addition, the structure of the ear cap 140 according to the embodiment of the present invention may have a structure in which upper and lower ends are different from each other so as to block external sounds even when wearing a blanket. When the user wears a bulletproof bomb during shooting training, it may be insufficient to allow the cap 140 to enter the space between the bullet and the ear. The upper end of the ear cap 140 may be formed to be thinner than the thickness of the lower end of the ear cap 140 so that the upper end of the ear cap 140 is inserted into the space between the burglar and the ear .

Hereinafter, the structure of the noise attenuator 100 and the ear cap 140 will be described in detail.

2 is a conceptual view showing a cross section of a sound attenuator according to an embodiment of the present invention.

2, the cross section of the sound attenuating part may be realized as a structure for absorbing sound of the porous structure of the polygonal structure 200. [ 2, it is assumed that the sound attenuation portion has a hexagonal polygonal structure 200 for convenience of explanation. However, a sound absorbing structure can be realized in various forms such as various polygonal structures, circular structures, or elliptical structures, rather than hexagonal shapes. Hereinafter, the embodiments of the present invention will be described using the term polygonal structure for convenience of explanation.

The polygonal structure 200 may be a structure for sound absorption and absorption. Noise and vibration can be transmitted through the solid medium, wherein the polygonal sound absorbing structure 200 can prevent the noise due to shooting from being transmitted through the noise attenuating portion of the headphone for noise shielding. And the internal space 220 of the noise attenuation unit may be vacuumed during the manufacturing of the noise attenuation unit. Sound does not propagate in vacuum. By utilizing the propagation characteristics of the sound, the internal space 220 of the polygonal structure can be implemented in a vacuum-state empty structure to prevent sound propagation.

Further, the noise attenuating portion may include an additional absorption structure. Noise can be transmitted through vibration of solid matter into the medium. An additional structure capable of preventing such vibration can be included in the sound attenuation portion. For example, the structure of a part of the noise attenuating part can be realized as a vibration absorbing material capable of absorbing vibration well. For example, a material such as latex or rubber may be used as the absorbent material. For example, the length adjusting unit described above with reference to FIG. 1 may be realized as a suction structure.

2 is a sectional view of a sound attenuating unit having a porous sound absorbing structure. However, according to another embodiment of the present invention, the inside of the sound attenuating unit forms one empty space and a porous structure is formed in the empty space of the sound attenuating unit. Or may be formed using a plurality of pipes.

3 is a conceptual view showing a section of a noise attenuator according to an embodiment of the present invention.

Referring to FIG. 3, the sound attenuating unit may have an empty space therein, and a plurality of tube bundles 300 may be filled in an empty space of the sound attenuating unit, so that the sound attenuating unit may perform sound absorption and absorption.

The plurality of tube bundles 300 may be formed of an elastic material, and the plurality of tubes 300 may be bent as an elastic material to fill an empty space of the noise attenuating portion. The plurality of tubes 300 and the empty space existing between the tubes and the tubes may be manufactured to be in a vacuum state by using a device such as a motor when manufacturing the noise attenuator. Since sound can not be transmitted in a vacuum state, the internal space of the sound attenuating part is realized in a vacuum state, so that a sound absorption effect can be obtained. In addition, the elastic material and the space existing in the inner space of the sound attenuating part may act to absorb the vibration by not transmitting the vibration directly to the helmet or the head of the person.

2 and 3, it is possible to have an improved noise shielding ratio over conventional noise shielding headphones.

In addition, the noise-shielding headphone according to the embodiment of the present invention may be different from the conventional noise-shielding headphone in that the shape of the sound-attenuating part is different from that of the existing noise-shielding headphone, considering the use of the burglar during shooting.

The noise attenuating unit may be realized in the form of FIG. 4 and FIG. 5 in consideration of the case in which a ball protector is first worn and a noise shielding headphone is worn thereon.

4 is a conceptual diagram illustrating a noise attenuator of a headphone for noise shielding according to an embodiment of the present invention.

Fig. 4 shows a case where a shooting person wore a burglar and wore a noise-shielding headphone. The sound attenuating part 400 of the noise shielding headphone can be positioned at the rear of the neck of the shooter. In other words, the noise attenuation unit 400 may be configured to surround the neck of the shooter in view of the use of the noise-shielding headphone. Referring to FIG. 4, the noise attenuator 400 may be configured to surround the rear neck of the shooter. The sound attenuating part 400 located at the neck part may block the sound transmitted through the body of the shooter and absorb the vibration.

In addition to this, there may be cases where wearing a burglar and wearing noise-shielding headphones on a burglar. As described above, the upper end 420-1 of the ear cap 420 may be formed to be thinner than the lower end so as to enter the space between the burglar and the ear. Or elastic material so that the space between the burgundy and the ears can be more closely attached based on the elasticity. By using such an ear cap structure, it is possible to improve the external noise shielding ratio of the headphone for shielding noise.

5 is a conceptual diagram illustrating a noise attenuator of a headphone for noise shielding according to an embodiment of the present invention.

FIG. 5 shows a case where a shooting person wears a burglar and wears a noise-shielding headphone. The sound attenuating part 500 of the noise shielding headphone can be worn in the form of covering the upper part of the bullet of the shooter. Considering the use of such a noise-shielding headphone, the noise attenuating part can be realized in a structure considering the size of the bulletproof hair. A sound absorbing structure for reducing vibrations between the burgundy and the noise shielding headphone may be additionally provided at the lower end of the sound attenuation portion. 4, the upper end of the ear cap 520 may be configured to be able to enter the space between the burglar and the ear. As described above, the ear cap 520 is provided with a speaker 520-1 to transmit an external signal to the shooter.

6 is a conceptual diagram illustrating a signal receiving unit of a noise attenuator according to an embodiment of the present invention.

Referring to FIG. 6, the noise attenuator may include a communication unit such as a signal receiver 600 therein. The noise attenuator may receive an externally transmitted signal based on the signal receiver 600 and transmit it to the shooter through a speaker provided in the ear cap of the shooter. Previously, a tool such as a microphone or a megaphone was used to control multiple personnel when performing firing. If you wear an earplug to block the noise, it may be difficult to control the shooter at the command because the outside command is not audible. In order to solve such a problem, the noise shielding headphone according to the embodiment of the present invention can be implemented such that the signal receiving unit 600 receives the voice signal transmitted from the external 620 based on the radio. The signal received by the signal receiving unit 600 may be output through a speaker provided in the ear cap. The wireless communication networking method for transmitting the signal of the exterior 620 may be performed on various networks. For example, an external signal may be transmitted to a signal receiving unit 600 of a headphone for noise shielding based on various networks such as Bluetooth, communication using a military frequency channel, communication using a conventional radio band, and cellular network.

According to another embodiment of the present invention, the external signal may be transmitted to the shooter through the bone conduction vibration element rather than the speaker provided in the ear cap. The method of transmitting a voice signal using a bone conduction vibration element is not a method of transmitting sound through the eardrum but a method of transmitting vibration through the bone to the cochlea. The method using the bone conduction vibration element can be an effective sound transmission method in a place with high noise. For example, a bone conduction vibration element may be provided on a part of an ear cap of a headphone for noise shielding to transmit a sound to a shooter through a bone conduction vibration element provided on the ear cap.

7 is a conceptual diagram illustrating a signal transmitter of a noise attenuator according to an embodiment of the present invention.

Referring to FIG. 7, a signal receiving unit for receiving a signal outside the communication unit 700 of the noise-shielding headphone may be used as a signal transmitting unit for transmitting a voice signal generated by a shooter to the outside.

For example, it can be assumed that a shooter's gun has an anomaly during shooting. The shooter needs to report to the commander about the failure of the gun. In such a case, the shooter's horse may not be transmitted to the command center due to the gun noise generated by other shooters in the vicinity. The headphone for shielding noise can receive the speech made by the shooter and transmit it through the communication unit 700. A microphone 700 may be provided as a headphone for noise shielding of a shooter in order to receive the speech of the shooter and transmit it through the communication unit 700. Through the microphone, the voice signal generated by the shooter can be transmitted to the command unit through the signal transmission unit.

8 is a conceptual diagram illustrating an ear cap according to an embodiment of the present invention.

Referring to FIG. 8, a speaker or a bone conduction vibration device may be provided in the ear cap to output a signal transmitted from the signal receiving unit of the sound attenuation unit. As described above, the signal receiving unit may be directly provided in the ear cap. In this case, the signal transmitted from the command unit may be directly input to the signal receiving unit of the ear cap.

The headphone for noise shielding according to the embodiment of the present invention can perform a noise cancellation method for noise reduction. The noise cancellation method is a method of removing an external noise by generating a reverse phase signal with respect to a noise signal based on a signal waveform of a noise. The noise cancellation method may be a method of removing noise by combining a signal having the same amplitude and a reverse phase and a generated noise signal.

In the case of the headphone for shielding noise according to the embodiment of the present invention, it can be used for military purposes. Noise that can occur during training in the military can be modeled in almost the same pattern because the noise sources are the same. In other words, the noise cancellation method may be separately performed to determine the noise, and the noise cancellation signal may be generated in consideration of the inverse phase and the signal size. However, in the noise cancellation method of the noise-shielded headphone according to the embodiment of the present invention, It is possible to generate a predetermined noise cancellation signal without needing to separately generate noise by modeling to generate a noise cancellation signal.

For example, noise shielding headphones can model gunfire as a source of noise and generate noise cancellation signals based on it. By using this method, a signal such as a command of a command unit which is not modeled as a noise source can be heard because the noise is not canceled relatively, and noise cancellation can be obtained by judging only the fire sound as a noise source. In other words, the noise shielding headphone cancels only the shot of the shooting range during the external sound, so that the shielding ratio against the gun sound is high and the command of the commander can implement the noise shielding headphone which sounds relatively well.

According to the embodiment of the present invention, the noise shielding headphone can adaptively generate the noise cancellation signal based on the noise model based on the result of noise modeling in various environments.

The noise generated in the military can be classified into various types according to the shooting equipment or the combat equipment to be used differently from the general noise. For example, when performing noise modeling, the noise generated by a rifle such as a general k-2, the noise caused by a heavy machine (90mm anti-roll gun, 81mm mortar, etc.), noise caused by a fighter or military helicopter It can have other noise characteristics.

That is, in most military training sites, the type of noise that is continuously generated can vary depending on the type of equipment and battle equipment being handled. Therefore, it is possible to shield noise based on noise cancellation signals that are differently modeled according to training sites.

A pre-modeled noise cancellation signal may be transmitted to the communication unit of the noise shielding headphone to generate a modeled noise cancellation signal received by the noise shielding headphone. For example, noise shielding headphones used in shooting sites receive information about noise cancellation signals from noise shielding headphones and external devices (e.g., computers, smart phones, notebooks, radios) that can form networking can do. The headphone for a noise canal may generate a noise cancellation signal based on information of the received noise cancellation signal. The noise shielding headphone according to the embodiment of the present invention can model the noise of a special site and adaptively generate a noise cancellation signal based on the modeled noise pattern.

It is possible to model a noise pattern in an external device other than a noise shielding headphone and generate a noise cancellation signal according to the modeled noise pattern so that only the information about the noise cancellation signal can be transmitted to the noise cancellation headphone. In another embodiment, the noise pattern may be modeled directly at the noise shielding headphone and the noise cancellation signal may be generated according to the modeled noise pattern.

9 is a conceptual diagram illustrating a noise cancellation signal generating method according to an embodiment of the present invention.

Referring to FIG. 9, the noise pattern is modeled based on the noise information (step S900).

The method of modeling the noise pattern may be performed in a separate device provided outside, but may also be performed in a headphone for noise shielding.

The noise shielding headphone may be provided with an operation button for performing an operation of modeling the noise pattern, for example. When performing the operation of modeling the noise pattern in the noise shielding headphones, external noise can be received through the input of the noise shielding headphone. The input for receiving external noise may be a microphone or other component of a noise shielding headphone capable of sensing external noise. Noise information (amplitude, phase, frequency, etc.) can be obtained by analyzing the external noise received from the noise shielding headphones.

The noise cancellation signal is determined based on the modeled noise pattern (step S910).

The noise cancellation signal may be a signal generated based on the modeled noise pattern information. As described above, the noise cancellation signal may be a signal having a reverse phase based on the noise information. The noise information may be various noises such as shot noise, fighter noise, explosion sound, etc., and a noise cancellation signal may be generated based on the noise pattern adaptively generated in the noise environment based on step S900.

And generates a noise canceling signal (step S920).

A noise cancellation signal may be generated in a noise-shielding headphone based on an input unit such as a button provided on a noise-shielding headphone. The noise cancellation signal generated through step S910 may be generated through a speaker of the headphone by a signal to start an operation of generating a noise cancellation signal transmitted from the outside at the start of shooting.

As described above, step S900 may be performed based on the external device and may transmit information on the determined noise cancellation signal from the outside to the headphone for noise shielding.

For example, signal information such as amplitude, phase, frequency, etc. of a signal to be generated as a noise cancellation signal may be transmitted to a signal receiving unit provided in a headphone for noise shielding in an external apparatus as a noise shielding headphone. In this case, the noise shielding headphone can generate a noise cancellation signal based on the received noise cancellation signal information.

10 is a conceptual view showing a headphone for shielding noise according to an embodiment of the present invention.

Fig. 10 shows a constitution of a noise-shielding headphone on the assumption that a noise-shielding headphone models a noise-canceling signal.

The noise shielding headphone may include a noise information receiving unit 1000, a noise pattern modeling unit 1020, a noise cancellation signal determiner 1040, and a noise cancellation signal generator 1060.

The noise information receiving unit 1000 can receive a signal generated from the noise generating source. The noise information receiving unit 1000 can receive noise information of a shooting range in a noise shielding headphone used in a shooting range and noise information of a helicopter in a noise shielding headphone used in a helicopter.

The noise pattern modeling unit 1020 may model a noise pattern based on the information obtained by the noise information receiving unit 1000. [ That is, the noise pattern modeling unit 1020 may be used to model a noise pattern characteristic of a noise source to generate a noise cancellation signal. For example, it is possible to generate a characteristic signal by modeling characteristics of noise by collecting frequency, amplitude, and period information of noise generated at a shooting range.

The noise cancellation signal determiner 1040 can determine the noise cancellation signal based on the noise information modeled by the noise pattern modeler 1020. The noise cancellation signal may be a signal of the same amplitude having a reverse phase of the modeled signal.

The noise cancellation signal generator 1060 may be a component that generates the noise cancellation signal determined by the noise cancellation signal determiner.

A noise shielding headphone for receiving only noise cancellation signal information transmitted from outside and generating a noise cancellation signal may include only a noise cancellation signal determiner 1040 and a noise cancellation signal generator 1060. The noise cancellation signal determiner 1040 can generate a noise cancellation signal based on the received noise cancellation signal information and the noise cancellation signal generator 1060 generates a noise cancellation signal determined by the noise cancellation signal determiner 1040 .

In this way, noise shielding headphones can adaptively block noise depending on the type of noise that can be generated during training in the military.

The configuration unit may be realized by dividing one configuration unit into a plurality of configuration units or by integrating a plurality of configuration units into one configuration unit. .

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

Claims (16)

A headphone for noise shielding,
Wherein the noise shielding headphone includes a sound attenuating part and an ear cap,
Wherein the noise attenuator has a band shape and is connected to the ear caps at both ends thereof,
The ear cap is formed in a cap shape to shield the ear while having an inner space in which an ear of a wearer of a headphone is shielded,
Wherein the noise attenuating part is configured such that a cross section of the noise attenuating part has a polygonal-shaped porous structure, the inside of the porous structure is in a vacuum state,
Wherein the noise attenuator includes a communication unit, the communication unit receives an externally transmitted signal,
Wherein the ear cap includes an output device, and the output device outputs the signal. The method of claim 1,
Headphone for noise shielding with hexagonal structure. The porous structure according to claim 1, wherein the polygonal-
And a plurality of pipes are included in the noise attenuating unit. 2. The apparatus according to claim 1,
Wherein the noise shielding headphone is configured to surround the wearer's neck wearing the noise shielding headphone. 2. The apparatus according to claim 1,
Wherein the noise shielding headphone is formed in a shape that surrounds the burgundy of a wearer wearing the noise shielding headphone. The ear cap according to claim 1,
Wherein a thickness of a portion shielding the upper end of the ear is smaller than a thickness of a portion shielding the lower end of the ear. 7. The ear shield according to claim 6,
Shielding headphone is mounted on the wearer's body so that a portion shielding the top of the ear is positioned in a space between the head of the wearer and the bulletproof cap Implemented noise shielding headphones. The headphone according to claim 1, wherein the noise shielding headphone further comprises a noise cancellation signal determiner and a noise cancellation signal generator,
Wherein the noise cancellation signal determiner is implemented to generate a noise cancellation signal based on the modeled noise pattern,
Wherein the noise cancellation signal generator is configured to output the noise cancellation signal determined by the noise cancellation signal determiner through the output device,
Wherein the noise cancellation signal is a reverse phase signal of a modeled noise pattern. 9. The headphone according to claim 8, wherein the noise-shielding headphone further comprises a noise information receiving unit and a noise pattern modeling unit,
Wherein the noise information receiver is configured to receive sound information from a noise source,
Wherein the noise pattern modeling unit is configured to model a feature of the sound information based on the sound information of the noise source. 10. The apparatus of claim 9,
Sound-isolating headphones including military equipment and noise sources located at industrial and medical sites. The apparatus according to claim 1,
Noise shielding headphones with speakers or bone conduction earphones. 2. The apparatus of claim 1, wherein the noise attenuator
And a sound absorbing material is additionally provided in a strip shape in a part thereof. The sound shielding headphone according to claim 1, further comprising a voice receiving unit,
Wherein the sound receiving unit is configured to receive a voice signal of a wearer of the noise shielding headphone. The sound attenuator according to claim 1, wherein the noise attenuator further comprises a length adjuster,
The length adjuster is configured to adjust the length of the band according to the individual body characteristics of the wearer of the noise shielding headphone,
Wherein the length adjuster is implemented as a sound absorbing material. A noise canceling signal generating method of a noise shielding headphone,
Receiving modeled noise pattern information;
Determining a noise cancellation signal based on the modeled noise pattern information; And
And outputting the determined noise cancellation signal,
Wherein the noise cancellation signal is a reverse phase signal of the modeled noise pattern,
Wherein the noise shielding headphone includes a noise attenuator, an ear cap, a noise cancellation signal determiner, and a noise signal generator,
Wherein the noise attenuator has a band shape and is connected to the ear caps at both ends thereof,
The ear cap is formed in a cap shape to shield the ear while having an inner space in which an ear of a wearer of a headphone is shielded,
Wherein the noise attenuating part is configured such that a cross section of the noise attenuating part has a polygonal-shaped porous structure, the inside of the porous structure is in a vacuum state,
Wherein the noise cancellation signal determiner is configured to generate the noise cancellation signal based on the modeled noise pattern,
Wherein the noise cancellation signal generator is configured to output the noise cancellation signal determined by the noise cancellation signal determiner through the output device. 16. The method of claim 15,
Receiving sound information from a noise source; And
Further comprising modeling a feature of the sound information based on sound information of the noise source,
Wherein the noise source comprises a military source and a noise source located at an industrial site and a medical site.

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