In an acoustic structure, sound absorbing effect is achieved by interference between incident waves falling in an opening portion and reflected waves radiated from the opening as a result of resonance occurring within a hollow member in response to the incident waves, and a sound absorbing region is
In an acoustic structure, sound absorbing effect is achieved by interference between incident waves falling in an opening portion and reflected waves radiated from the opening as a result of resonance occurring within a hollow member in response to the incident waves, and a sound absorbing region is formed, for example, in a frontal direction of the opening portion. Sound scattering effect is achieved through interaction between the above-mentioned interference and interference between the incident waves and sound waves radiated from the opening portion, and a sound scattering region is formed, for example, near the sound absorbing region. A sound scattering effect is achieved by flows of gas molecules being produced in an oblique direction, not normal to the opening portion and reflective surface, due to a phase difference between the sound waves radiated from the opening portion and the sound waves radiated from the reflective surface.
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1. An acoustic structure comprising a hollow member, said hollow member adapted to be disposed close to a reflective surface which faces to an external space, said hollow member comprising: a hollow region formed in the hollow member; andan opening portion communicating the hollow member with the ex
1. An acoustic structure comprising a hollow member, said hollow member adapted to be disposed close to a reflective surface which faces to an external space, said hollow member comprising: a hollow region formed in the hollow member; andan opening portion communicating the hollow member with the external space,wherein the hollow member is disposed close to the reflective surface in such a manner that the opening portion of the hollow member is disposed adjacent to the reflective surface,wherein incident sound waves fall in the opening portion and fall on the reflective surface from the external space,wherein a space portion of the hollow region adjoining and communicating with said opening portion is constructed as an intermediate layer, and a portion of said hollow region extending from one end of the hollow region to the intermediate layer is constructed as a resonator, andwherein the hollow member is configured such that a ratio of an area of the opening portion to an area of a boundary surface between the resonator and the intermediate layer decreases. 2. The acoustic structure as claimed in claim 1, wherein the opening portion lies in non-parallel relation to the reflective surface. 3. The acoustic structure as claimed in claim 2, wherein the opening portion lies in a direction normal to the reflective surface. 4. The acoustic structure as claimed in claim 1, wherein a sectional size of the hollow region in a direction normal to the extended direction of the hollow region is considerably small as compared to a wavelength of a resonant frequency of the resonator. 5. The acoustic structure as claimed in claim 1, wherein the hollow region has a first and second portions, the first portion of said hollow region extending from one end of the hollow region to the intermediate layer to be constructed as a first resonator, the second portion of said hollow region extending from another end of the hollow region to the intermediate layer to be constructed as a second resonator. 6. The acoustic structure as claimed in claim 1, wherein said intermediate layer is located at one end of said hollow region, and the portion of said hollow region constructed as the resonator extends from another end of the hollow region to the intermediate layer. 7. The acoustic structure as claimed in claim 1, wherein said hollow member forms a plurality of the hollow regions partitioned from each other by a partition wall, and wherein each of said plurality of the opening portions is provided in a different one of the hollow regions. 8. The acoustic structure as claimed in claim 1, wherein said hollow member forms a plurality of the hollow regions disposed at an angle relative to each other. 9. The acoustic structure as claimed in claim 1, wherein said opening portion is covered with a material having a sound pressure transmission characteristic. 10. The acoustic structure as claimed in claim 1, wherein said hollow member has a slide structure for variably adjusting a length of said hollow region. 11. The acoustic structure as claimed in claim 1, which is adapted to be provided in a predetermined structure of a musical instrument. 12. The acoustic structure as claimed in claim 1, which is adapted to be provided in at least one of fittings, illumination device, wall and ceiling of an acoustic room and other building structure. 13. An acoustic structure comprising a hollow member, said hollow member adapted to be disposed close to a reflective surface which faces to an external space, said hollow member comprising: a hollow region formed in the hollow member; andan opening portion communicating the hollow member with the external space,wherein the hollow member is disposed close to the reflective surface in such a manner that the opening portion of the hollow member is disposed adjacent to the reflective surface,wherein a space portion of the hollow region adjoining and communicating with said opening portion is constructed as an intermediate layer, and a portion of said hollow region extending from one end of the hollow region to the intermediate layer is constructed as a resonator,wherein, when the reflective surface radiates reflected waves, said resonator resonates in response to the incident sound waves and radiates reflected waves, differing in phase from the reflected waves from said reflective surface, via the opening portion, andwherein a layer of gas where sound pressure is distributed uniformly is provided between the portion of said hollow region as the resonator and the opening portion, and an absolute value of a motion velocity of medium particles in the opening portion is greater than an absolute value of a motion velocity of medium particles on a boundary surface between the hollow region and the layer of gas. 14. The acoustic structure as claimed in claim 1, wherein the opening portion has a square shape with sides of distance d, and each side of the opening portion satisfies relationship of d<λ/6 with respect to a wavelength λ corresponding to a resonance frequency of the resonator. 15. The acoustic structure as claimed in claim 1, wherein said intermediate layer is constructed in such a manner that, when the reflective surface radiates reflected waves corresponding to incident sound waves falling from the external space on said opening portion and the reflective surface of said hollow member, said intermediate layer not only causes reflected waves, produced through resonance of said resonator and differing in phase from the reflected waves from said reflective surface, to be radiated from said opening portion but also makes less than an absolute value of a value obtained by dividing a specific acoustic impedance of said opening portion, at a time of radiation of the reflected waves from said opening portion, by a characteristic impedance of a medium of said portion for the incident sound waves of resonance frequency band. 16. The acoustic structure as claimed in claim 15, wherein said intermediate layer is constructed in such a manner that, when the reflective surface radiates the reflected waves corresponding to the incident sound waves falling from the external space on said opening portion and the reflective surface of said hollow member, a real part of the value obtained by dividing the specific acoustic impedance of said opening portion by the characteristic impedance of the medium of said opening portion is substantially zero for the incident sound waves of the resonance frequency band.
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이 특허에 인용된 특허 (12)
Van Ligten Robert,CHX, .lambda./4 absorber with an adjustable band width.
Woodward Bruce (912 Baxter Ave. Louisville KY 40204) Martin Daniel W. (912 Baxter Ave. Louisville KY 40204) Miller William (912 Baxter Ave. Louisville KY 40204), Sound absorbing structures.
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