Patent Grant
9473847
The present application claims priority from Japanese Application No. JP 2013-045964. The content of the application is hereby incorporated by reference into this application.
1. Field of the Invention
The present invention relates to an acoustic apparatus.
2. Description of the Related Art
It is known that when sound waves of a natural frequency are emitted in space surrounded by walls of acoustic equipment, standing waves are produced by the reciprocal motion of the sound waves between the wall surfaces of the space, which affect the acoustic characteristics of the acoustic equipment. Japanese Patent No. 2606447, Japanese Patent No. 3763682, and Japanese Patent Application Laid-open No. 2008-131199 disclose techniques of suppressing standing waves in a loudspeaker which is one type of acoustic equipment. A speaker apparatus disclosed in Japanese Patent No. 2606447 includes a speaker unit, a cabinet housing the speaker unit, and a Helmholtz resonator provided in the cabinet. A neck length L and a cavity volume V of the Helmholtz resonator in the speaker apparatus are designed in such a way that the Helmholtz resonator resonates at the same frequency as that of standing waves present in the cabinet. When a standing wave is produced in the cabinet of this speaker apparatus, the resonance phenomenon of the Helmholtz resonator occurs, attenuating the standing wave. A speaker apparatus disclosed in Japanese Patent No. 3763682 includes a speaker unit, a cabinet housing the speaker unit, and an acoustic tube (closed tube) having an open end and a closed end. The acoustic tube of the speaker apparatus has a tube length L which is a quarter of a wave length corresponding to the lowest resonance mode of a standing wave produced in the cabinet. This acoustic tube is housed in the cabinet in such a state where the position of its open end comes close to the position of the anti-node (node of the particle velocity) of the sound pressure of the standing wave in the cabinet. When a standing wave (whose wavelength is four times the tube length L) is produced in the cabinet of this speaker apparatus, a resonance wave is produced in the acoustic tube. This resonance wave has a node (anti-node of the particle velocity) of a sound pressure at the open end of the acoustic tube, and an anti-node (node of the particle velocity) of the sound pressure at the closed end. Accordingly, the speaker apparatus relaxes biasing of the distribution of the sound pressure in the cabinet, attenuating the standing wave in the cabinet. Japanese Patent Application Laid-open No. 2008-131199 also discloses a technique similar to the technique of Japanese Patent No. 3763682.
A speaker apparatus for reproducing high audio frequencies, which is called “tweeter”, includes a chamber or a closed tube to widen the reproduction range, at the back of a driver serving as a vibration source. With such a chambered tweeter, a standing wave is likely to be produced in the closed space surrounded by the driver and the chamber. As a result, a large peak dip occurs in the emission characteristics of the tweeter, lowering the sound quality. A possible solution to this problem is to dispose the aforementioned Helmholtz resonator or acoustic tube in the chamber of the tweeter. However, the chamber of the tweeter is a very slender tube body, so that it is difficult to dispose the Helmholtz resonator, the acoustic tube, or the like therein. An effective way of improving the emission characteristics of the tweeter has not been provided.
Accordingly, one object of one or more embodiments of the present invention is to suppress standing waves produced in a chamber in an acoustic apparatus having the chamber, such as a tweeter.
(1) In one or more embodiments of the present invention, an acoustic apparatus includes a vibration part configured to generate an acoustic vibration and a tube having a cavity that faces the vibration part, and at least one open tube connected to the tube via a first open end and a second open end. A length of the at least one open tube is an integer-fold of substantially a half of a wavelength of a standing wave produced in the tube. The first open end is positioned substantially at an anti-node of the standing wave produced in the tube.
(2) In the acoustic apparatus according to (1), the second open end is positioned substantially at a node of the standing wave produced in the tube.
(3) In the acoustic apparatus according to (1) or (2), the first open end and the second open end are positioned at positions apart from each other in an axial direction of the tube by a length of an odd-numbered fold of substantially a quarter of the wavelength of the standing wave.
(4) In the acoustic apparatus according to (1), the second open end is positioned substantially at an anti-node of the standing wave produced in the tube.
(5) In the acoustic apparatus according to one of (1) to (4), at least one of the first open end and the second open end is entirely or partly covered with a permeable sound absorbing material.
(6) In the acoustic apparatus according to one of (1) to (5), the open tube is provided outside the tube.
(7) In the acoustic apparatus according to one of (1) to (6), the first open end is positioned substantially at the anti-node located far from the vibration part.
(8) In the acoustic apparatus according to one of (1) to (7), a number of the at least one open tube is two, and the two open tubes are disposed to face each other across the tube.
(9) In the acoustic apparatus according to (8), the acoustic apparatus further includes a cabinet for housing the vibration part, the tube, and the two open tubes. The two open tubes are provided substantially in parallel to a bottom surface of the cabinet.
(10) In the acoustic apparatus according to (8) or (9), the two open tubes and the tube are formed as an opening of a chamber.
(11) In the acoustic apparatus according to (10), the chamber has a cylindrical chamber body and a wing part that extends sideward from the cylindrical chamber body as the wing part is positioned away from the vibration part. The tube is formed as an opening of the cylindrical chamber body. The two open tubes are formed as through holes of the wing part.
(12) In the acoustic apparatus according to one of (1) to (11), the acoustic apparatus further includes a plurality of the vibration parts that have different frequency characteristics respectively. The tube and the open tube are provided for each of the plurality of the vibration parts except at least the vibration part having a lowest frequency characteristic among the plurality of the vibration parts.
(13) In the acoustic apparatus according to one of (1) to (12), an inside diameter of the open tube is smaller than an inside diameter of the tube.
(14) In the acoustic apparatus according to one of (1) to (13), the acoustic apparatus includes a loudspeaker.
Referring to the accompanying drawings, an embodiment of the present invention is described hereinbelow.
A first feature of this embodiment resides in the open tubes 21 and 22. According to this embodiment, the open tubes 21 and 22 give the following effect. When an electric signal is supplied from the amplifier (not shown), the driver 10 emits sound waves both rearward and forward. The sound waves emitted rearward by the driver 10 propagate through the space in the chamber 20. Frequency components in the sound waves emitted by the driver 10, having a frequency that is the same as the natural frequency in the space in the chamber 20, reciprocate in the chamber 20 between the driver 10 and the closed end of the chamber 20. A plurality of sound waves reciprocally traveling this way are combined to produce standing waves SWk (k=1, 2, . . . ) having a wavelength λk=2L/k (k=1, 2, . . . ) which is 2/k (k=1, 2, . . . ) times a tube length L of the chamber 20.
Regarding the sound pressure component of the second-order standing wave SW2 produced in the chamber 20, the anti-node of a sound pressure opposite in phase to the anti-node of the sound pressure produced at the closed end of the chamber 20 is produced near the center of the chamber 20. The standing wave SW2 is phase-delayed by 2π during the propagation in the open tubes 21 and 22 from the open ends 21b and 22b, and reaches the open ends 21a and 22a. In other words, the anti-node opposite in phase to the anti-node of the sound pressure waveform of the standing wave SW2 produced in the chamber 20 reaches near the closed end of the chamber 20 through the open tubes 21 and 22. As a result, the standing wave SW2 in the chamber 20 is suppressed.
Regarding the sound pressure component of the fourth-order standing wave SW4 produced in the chamber 20, the anti-node of a soundpressure in phase to the anti-node of the soundpressure produced at the closed end of the chamber 20 is produced near the center of the chamber 20. The standing wave SW4 is phase-delayed by 4π during the propagation in the open tubes 21 and 22 from the open ends 21b and 22b, and reaches the open ends 21a and 22a. Therefore, the fourth-order standing wave SW4 is not suppressed in the chamber 20.
As apparent from the above, according to this embodiment, the connection of the open tubes 21 and 22 to the chamber 20 can suppress the first-order to fifth-order standing waves, except the fourth-order standing wave. Because the anti-nodes of the sound pressures of various standing waves which are to be suppressed are positioned in the center of the chamber 20 in this example, the open ends 21b and 22b are provided in the center of the chamber 20. When the anti-nodes of the sound pressures of standing waves to be suppressed are produced at positions other than the center of the chamber 20, however, the open ends 21b and 22b may be provided there.
A second feature of this embodiment resides in the locations of the sound absorbing materials 23. The sound absorbing materials 23 disposed in the region near the open ends 21a and 22a in the chamber 20 and the region near the open ends 21b and 22b therein demonstrate the following effect. Those two regions are the boundary regions between the chamber 20 and the open tubes 21 and 22 where the airstream flows fast and the energy of sounds tends to focus in the chamber 20. Therefore, the sound absorbing materials 23 disposed in those regions can efficiently absorb the energy of sounds in the chamber 20. In other words, the sound absorbing materials 23 disposed in the boundary regions between the chamber 20 and the open tubes 21 and 22 can demonstrate the effect of efficiently absorbing the energy of sound from standing waves in the chamber 20.
The inventors of the present invention conducted simulations to check the effects of this embodiment. Specifically, the sound pressure levels of sounds emitted from the tweeter and the electric impedances of the driver were obtained through simulation while changing the frequency of a test signal supplied to the driver of the tweeter.
As apparent from the above, according to this embodiment, the provision of the open tubes 21 and 22 in the chamber 20 of the tweeter can suppress standing waves produced in the chamber 20, and thus improve the acoustic characteristics of the tweeter. In addition, according to this embodiment, the sound absorbing materials are filled only in the boundary regions with respect to the open tubes 21 and 22 in the chamber 20, thereby saving a large amount of sound absorbing materials as compared to the case where the sound absorbing material is filled in the entire region inside the chamber 20. This leads to cost reduction, and thus a problem which otherwise occurs when a large amount of sound absorbing material is used can be avoided. In other words, when the sound absorbing material is filled in the entire region inside the chamber 20, wave components other than standing waves produced in the chamber 20 are also attenuated, which undesirably affects the acoustic characteristics of the tweeter. When the sound absorbing materials are filled only in the boundary regions with respect to the open tubes 21 and 22 in the chamber 20 according to this embodiment, the adverse influence can be avoided.
The following describes specific examples of a chamber provided with an open tube which is usable in this embodiment.
According to the first to fourth examples described above, the open ends of the open tube having an adequate tube length in accordance with the wavelengths of standing waves to be suppressed are provided at proper positions in the chamber, and hence standing waves which are produced in the chamber can be suppressed to improve the acoustic characteristics of the tweeter. Further, arranging sound absorbing materials at the boundary regions with respect to the open tube in the chamber, though not illustrated, can efficiently reduce unnecessary standing waves in the chamber.
A limited number of embodiments are described above, and the present invention is not limited to the above embodiments.
In the above-described embodiments, in the chamber, both of the two open ends of the open tube are entirely covered with permeable sound absorbing materials. However, both of the two open ends of the open tube may be covered partly with permeable sound absorbing materials, or one of the two open ends of the open tube may be entirely or partly covered with permeable sound absorbing materials, as long as a sufficient effect of attenuating standing waves is obtained.
In the above-described embodiments, one or more embodiments of the present invention are adapted to a tweeter. However, one or more embodiments of the present invention are not limited to be applied to a speaker such as a tweeter. For example, one or more embodiments of the present invention may be adapted to a muffler of a motorcycle, or may be adapted to a squawker or the like.
In the above-described embodiments, the length of the open tube that connects to the chamber corresponds to a half of the wavelength of the lowest-order standing wave among the standing waves to be suppressed. However, the length of the open tube may not necessarily exactly correspond to a half of the wavelength of the lowest-order standing wave among the standing waves to be suppressed, and has only to be an integer-fold of approximately a half of that wavelength. In this case, effects similar to those of the above-described embodiment can be obtained.
In the above-described embodiments, the positions of the two open ends of the open tube that connects to the chamber are set apart along the axial direction of the chamber by a quarter of the wavelength of the lowest-order standing wave among the standing waves to be suppressed. However, the two open ends may not necessarily be set apart exactly by a quarter of the wavelength of the lowest-order standing wave, and have only to be set apart by an odd-numbered fold of approximately a quarter of that wavelength. In this case, effects similar to those of the above-described embodiment can be obtained.
As illustrated in
Further, as illustrated in
Moreover, as illustrated in
Furthermore, an inside diameter of the open tube may be smaller than an inside diameter of the tube as illustrated in
In addition, the lengths of the tube and the open tubes may be determined based on the length of a portion that has substantially the same diameter. Specifically, in the case illustrated in
While the invention has been described with respect to a limited number of embodiments, those skilled in the art, having benefit of this disclosure, will appreciate that other embodiments can be advised which do not depart from the scope of the invention as described therein. Accordingly, the scope of the invention should be limited only by the claims.
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| 2013-045964 | Mar 2013 | JP | national |
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| Entry |
|---|
| Mechanical English translation of document B1 (JP 2606447 B2) previously filed on Mar. 6, 2014. |
| Mechanical English translation of document B2 (JP 3763682 B2) previously filed on Mar. 6, 2014. |
| Mechanical English translation of document B3 (JP 2008-131199 A) previously filed on Mar. 6, 2014. |
| Number | Date | Country | |
|---|---|---|---|
| 20140254839 A1 | Sep 2014 | US |
