KR100880240B1 - Resonance sound wave generator - Google Patents

Abstract

A sound wave resonance generator is provided to produce the electricity by resonating noise after sound-collecting the noise on the place where the noise is very much generated. A sound wave resonance generator comprises a sound collecting pipe(10) for sound-collecting the sound of neighboring; a cavity resonator(20) for resonating the sound which is connected to the backend of the sound collecting pipe and is sound-gathered; a plurality of resonators(30) installed at the outer sidewall of the cavity resonator; an actuator(40) installed at the end part of each resonator in the resonance direction; and a stator(50) which generates the electromotive force induced with the oscillation of actuator and outputted.

Description

Resonance sound wave generator

The present invention relates to a sound wave resonance generator, in particular installed in the underground tracks of subways or a lot of noise, such as tunnels of general roads or airplane landings of airports to collect ambient noise to convert the vibration of the resonator, The present invention relates to a sonic resonance generator which converts vibrational motion into electric energy and makes it available.

In general, as a method of producing electricity, technologies for obtaining electricity from various energy sources such as thermal power generation, nuclear power generation, hydro power generation, solar power generation, wind power generation, wave / tidal power generation with large-scale power generation facilities have been developed. It is used a lot.

Recently, as interest in pollution-free energy increases, technologies for obtaining electricity from energy sources such as solar light, wind power, tidal power, and wave power are getting more attention, and various methods have been studied in terms of energy production.

By the way, sound waves, that is, sound can be regarded as a kind of energy having a wavelength, and power generation equipment using such sound waves is not known yet. Although very loud noises are generated in subways, airfields and tunnels, these noises are being dissipated as noises and there is no way to utilize them.

The present invention is to provide a sound wave resonance generator capable of obtaining electricity by using sound waves.

The present invention installs a sonic resonance generator in a place where a lot of loud noise occurs, such as underground subway tracks, tunnels of general roads, take-off and landing of the airfield, and collect the noise to resonate to produce electricity and can be used as a self-guided lighting using this electricity So as to provide one sonic resonance generator.

Sound wave resonance generator according to the present invention,

A sound collecting pipe for collecting sound around; A resonance passage connected to a rear end of the sound collecting pipe for resonating the collected sound; A plurality of resonators attached to an outer wall of the resonator to resonate with sound waves transmitted through the resonator to generate vibrations; Actuators arranged alternately and repeatedly with magnetic poles of the magnets installed in the resonant direction at end portions of the resonators, the actuators reciprocating by resonance of the resonators; Coils are arranged in correspondence with the actuator, characterized in that it comprises a stator for generating and outputting electromotive force induced by the reciprocating motion of the actuator.

The sound wave resonance generator,

An enclosure that is installed to surround the resonance cylinder at a predetermined interval so as to form a resonance chamber in which the resonator, the actuator and the stator are installed, supports the resonance cylinder, fixes the stators, and opens both ends thereof; A diaphragm installed between the open end surfaces of the enclosure and the resonance cylinder to seal an resonance chamber in which the resonator is installed, and to allow air flow during resonance of the resonator; A resonance adjusting plate installed inside the resonance cylinder to adjust an optimal standing wave ratio, that is, a maximum resonance point, by adjusting a volume of an inner region of the resonance cylinder; It is installed to expose the rear end of the resonance tube is characterized in that it further comprises a resonance regulator for controlling the forward and backward of the resonance control plate.

The sound collecting tube has a wide outer end and a narrow inner tube connected to a resonance tube in the form of a fallopian tube, and a spiral protrusion is formed on the inner wall of the fallopian tube, characterized in that it is configured in the form of a cochlea.

In addition, the stator is configured to output the induced electromotive force to the outside, and is configured to charge the charging battery through a voltage stabilization circuit and a double voltage circuit from the outside, or directly supply the power to a load (eg, a lamp) driving power.

The resonance generator according to the present invention is installed on a side wall of an underground railway line, an airfield or a tunnel, and collects ambient noise to generate electricity to drive a load. When the external sound is collected by the sound collecting tube, sound waves are delivered to the inside of the resonance tube, and the resonance tube is resonated by the transmitted sound waves, and the resonator attached to the outer wall of the resonance tube resonates.

The resonator vibrates at an end portion of the sound wave. At this time, the actuator attached to the end of the resonator performs a horizontal vibration movement according to the resonance of the resonator, and since the actuator is composed of a magnet array and the stator is composed of a coil array, when the actuator is vibrated by a horizontal reciprocating motion, By electromotive force is induced to generate power. The power can be charged and boosted using an external power supply to drive the load.

The resonant chamber formed by the enclosure may be sealed by diaphragms at both ends to allow air flow generated when the resonator is resonated, and also to block external air due to sealing with the outside, thereby achieving stable resonance. And the resonance cylinder is installed inside the resonance control plate to adjust the internal volume of the resonance tube ratio, that is, it can be adjusted by moving the resonance control plate forward / backward by operating the resonance controller from the outside.

Since the resonance generator of the present invention collects sound and installs a resonator that is resonated and resonated by sound, and generates electricity in a manner of inducing power to the stator coil by horizontally reciprocating the actuator by resonance of the resonator, Installed in a place where a lot of noise is generated there is an effect that can be used to drive the load by converting the noise into power. Therefore, there is an effect that can be used as a driving power source of the light by installing a sound wave resonance generator in the place where noise, such as subway, tunnel, airfield.

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

1 is a block diagram of a sound wave resonance generator according to the present invention.

A sound collecting pipe (10) for collecting sound around; A resonance tube 20 connected to the rear end of the sound collecting tube 20 for resonating the collected sound; A plurality of resonators (30) attached to an outer wall of the resonator (20) and resonating to sound wave waves transmitted through the resonator (20) to generate vibrations; Actuators (40) arranged in alternating repetition of the magnetic poles of the magnets in the resonant direction at the ends of the resonators (30) and reciprocating by the resonance of the resonators (30); Coils are arranged in correspondence with the actuator 40, and the stator 50 is configured to generate and output electromotive force induced by the reciprocating motion of the actuator 40.

The sound wave resonance generator,

The resonator 30 and the actuator 40 and the stator 50 is installed so as to surround the resonator chamber 61 is formed to be spaced apart at a predetermined interval to the outer side of the resonance cylinder 20, and supports the resonance cylinder 20 In addition, the stator 50 is fixed and installed, both ends of the enclosure (60) open; The diaphragm is installed between the open end surface of the enclosure 60 and the resonance cylinder 20 to seal the resonator chamber 61 in which the resonator 30 is installed, and to allow air flow during the resonance of the resonator 30 ( 70); A resonance adjusting plate (80) installed inside the resonance cylinder (20) for adjusting the size of an inner region of the resonance cylinder (20); Exposed to the rear end of the resonance cylinder 20 is configured to further include a resonance controller 90 for controlling the forward and backward of the resonance control plate 80.

2A and 2B are exemplary views illustrating the configuration of an actuator and a stator of the acoustic resonance generator according to the present invention. Coils corresponding to the actuators 40 are arranged in the circular stator brackets so that electric power is induced in the coils by the reciprocating motion of the actuators 40, and the stator brackets are fixed to the enclosure 60. The actuator arranges a plurality of magnets so that the polarities of the magnets are alternately repeated.

3 is a horizontal cross-sectional view of the sound wave resonance generator according to the present invention, as shown therein,

While installing a plurality of resonators on the outer circumferential surface of the resonance cylinder 20, in accordance with an embodiment of the present invention, the resonator 30 is provided in each of the four directions, the actuator 40 is provided in each resonator 30, respectively, the actuator ( It is a structure in which the stator 50 is provided correspondingly every 40).

The sound collecting tube 10 has a wide outer end and a narrow fallopian tube inner end connected to the resonance tube 20. A spiral protrusion 11 is formed on an inner wall of the fallopian tube to form a cochlear tube.

In addition, although not shown in the drawings, it is a natural configuration to further include a power supply for stabilizing the output of the stator 50 to supply the load driving power. Usually, the power supply device is configured to charge the output of the stator to the charging battery via a rectifier circuit, a voltage stabilizer circuit, a double voltage circuit, or the like, or to supply a load (for example, a lamp) driving power.

The resonance generator according to the present invention is installed on a side wall of an underground railway line, an airfield or a tunnel, and collects ambient noise to generate electricity to drive a load. When the external sound is collected by the sound collecting tube 10, sound waves are delivered to the inside of the resonance tube 20, and the resonance tube 20 is resonated by the sound waves transmitted and collected, and the resonator is attached to the outer wall of the resonance tube 20 ( 30 is resonant. The sound collecting pipe 10 is formed as a cochlea formed with a spiral protrusion on the inner wall, as shown in the drawing, so that sound waves introduced from the outside are collected into the resonance tube 20 through the spiral cochlea.

The resonator 30 is the end of the resonator 30 is vibrated by the sound waves transmitted through the resonance cylinder 20 to resonate. The resonator 30 may be composed of an iron plate made of a conventional horseshoe magnet form. At this time, the actuator 40 attached to the end of the resonator 30 is a horizontal vibration movement in accordance with the resonance of the resonator 30.

As the actuator 40 is composed of a magnet array and the stator 50 is a coil arrangement, as shown in FIG. 2, when the actuator 40 is vibrated in a horizontal reciprocating motion, the stator 50, which is a coil, is applied to a magnetic field. By electromotive force is induced to generate power. The power can be charged and boosted using an external power supply to drive the load.

Since the resonance chamber formed by the enclosure 60 is formed in a sealed form by the diaphragms 70 at both ends, the air flow generated when the resonator 30 is resonant is enabled, and the air pressure fluctuates due to sealing with the outside. And stable resonance can be achieved.

Therefore, the acoustic wave resonator generator according to the present invention, by collecting the noise of the subway, airfield or tunnel through the sound collecting pipe 10 to vibrate the actuator 40 through the resonance cylinder 20 and the resonator 30 to the stator 40 It can be converted into electrical energy through the use.

1 is a block diagram of a sound wave resonance generator according to the present invention.

Figure 2a and 2b is an example of the configuration of the actuator and the stator of the acoustic resonance generator according to the present invention,

3 is a horizontal cross-sectional view of a sound wave resonance generator according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: sound collection pipe 20: resonance tube

30: resonator 40: actuator

50: stator 60: enclosure

70: diaphragm 80: resonance control plate

90: resonance regulator

Claims (5)

A sound collecting pipe (10) for collecting sound around; A resonance tube 20 connected to the rear end of the sound collecting tube 20 for resonating the collected sound;  A plurality of resonators (30) attached to an outer wall of the resonator (20) and resonating to sound wave waves transmitted through the resonator (20) to generate vibrations; Actuators (40) arranged in alternating repetition of the magnetic poles of the permanent magnets in the resonant direction at the ends of the resonators (30) and reciprocating by the resonance of the resonators (30); And a stator (50) arranged in correspondence to the actuator (40), the stator (50) generating and outputting electromotive force induced by the reciprocating motion of the actuator (40). According to claim 1, The sound wave resonance generator, The resonator 30 and the actuator 40 and the stator 50 is installed so as to surround the resonator chamber 61 is formed to be spaced apart at a predetermined interval to the outer side of the resonance cylinder 20, and supports the resonance cylinder 20 In addition, the stator 50 is fixed and installed, both ends of the enclosure (60) open; The diaphragm installed between the opened both end surfaces of the enclosure 60 and the resonance cylinder 20 to seal the resonator chamber 61 in which the resonator 30 is installed and to allow air flow during the resonance of the resonator 30. 70 and; A resonance adjusting plate (80) installed inside the resonance cylinder (20) for adjusting the volume of the inner region of the resonance cylinder (20) to adjust the maximum resonance point which is an internal refinement ratio of the resonance cylinder; The sound wave resonance generator, characterized in that it further comprises a resonance regulator (90) for controlling the forward and backward of the resonance control plate 80 is installed exposed in the rear end of the resonance tube (20). According to claim 1, wherein the actuator 40, a plurality of permanent magnets are arranged in a row so that the polarity of the permanent magnet alternately, The stator 50, the coil corresponding to the permanent magnet of the actuator 40 is arranged inside the circular stator bracket, characterized in that configured to induce power to the coil by the reciprocating motion of the actuator 40 Sonic resonance generator. According to claim 1, The sound wave resonance generator, The resonators 30 are respectively provided in four directions on the outer circumferential surface of the resonance cylinder 20, the actuators 40 are installed in each resonator 30, and the stator 50 is installed to correspond to each actuator 40. Sound wave resonance generator characterized in that the structure. The method of claim 1, wherein the sound collecting tube 10, the outer end is wide, the inner end connected to the resonance tube 20 is a narrow fallopian tube shape, the spiral protrusion 11 is formed on the inner wall of the fallopian tube is characterized in that it is configured in the cochlear shape. Sound wave resonance generator.

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