The present invention relates to techniques for preventing acoustic inconveniences in acoustic spaces.
In an acoustic space, such as a hall or theater, surrounded by walls, acoustic inconveniences, such as booming and flatter echoes, may occur by sounds being repeatedly reflected between the walls opposed parallel to each other.
In the thus-constructed acoustic structure, each of the pipes 51-j (j=1-7) resonates in response to sound waves of a particular resonance frequency of sound waves falling from the acoustic space in the individual opening portions 52-j (j=1-7). Because of such resonance, sound waves radiated from interior hollow regions of the pipes 51-j (j=1-7) to the acoustic space via the opening portions 52-j (j=1-7) produce sound absorbing and sound scattering effects near the opening portions 52-j (j=1-7). As a consequence, sound waves propagated from the acoustic space toward the pipes 51-j (j=1-7) are dissipated in the pipes 51-j (j=1-7), so that occurrence of acoustic inconveniences can be prevented. An example of this type of acoustic structure 50 is disclosed in Japanese Patent Application Laid-open Publication No. 2002-30744 (patent literature 1).
In the aforementioned type of acoustic structure 50, the sound absorbing and sound scattering effects are produced at resonant frequencies determined by respective constructions of the pipes 51-j (j=1-7). Each of the pipes 51-j (j=1-7) has not only a fundamental resonance mode but also a high-order resonance mode. Thus, the acoustic structure 50 can achieve sound absorbing and sound scattering effects over wide frequency bands by causing each of the pipes 51-j (j=1-7) to resonate not only in the fundamental resonance mode but also in the high-order resonance mode.
Actually, however, with the pipes 51-j of the acoustic structure 50, sound absorbing and sound scattering effects produced in response to sound waves of high frequency bands, particularly in a range of 2 kHz-4 kHz, entering or falling in the opening portions 52-j are smaller than sound absorbing and sound scattering effects produced in response to sound waves of low frequency bands falling in the opening portions 52-j (j=1-7). Thus, when sound waves of high frequency bands have been produced in the acoustic space, acoustic energy of the produced sound waves cannot be dissipated sufficiently with the pipes 51-j.
In view of the foregoing, it is an object of the present invention to provide an improved acoustic structure, which comprises: plate members defining at least one hollow region, and having at least one opening portion formed in a part of thereof in such a manner as to communicate the at least one hollow region with an external space; and a sound absorbing member disposed on a region of an outer surface of the plate members other than the opening portion and a neighborhood of the opening portion.
Once sound waves of high frequency bands, for which sound absorbing and sound scattering effects are difficult to occur, fall on the acoustic structure of the present invention, acoustic energy of the sound waves is dissipated by the sound absorbing member. Thus, even when sound waves of high frequency bands are being produced in an acoustic space (external space), the acoustic structure of the present invention can reliably prevent acoustic inconveniences from occurring in the acoustic space.
According to another aspect of the present invention, there is provided an acoustic structure, which comprises: plate members defining a plurality of hollow regions, and having a plurality of opening portions formed therein in such a manner as to communicate individual ones of the hollow regions with an external space; and a sound absorbing member loaded in at least one of the plurality of hollow regions, the sound absorbing member being partly exposed to the external space through the opening portion corresponding to the at least one hollow region.
The following will describe embodiments of the present invention, but it should be appreciated that the present invention is not limited to the described embodiments and various modifications of the invention are possible without departing from the basic principles. The scope of the present invention is therefore to be determined solely by the appended claims.
For better understanding of the object and other features of the present invention, its preferred embodiments will be described hereinbelow in greater detail with reference to the accompanying drawings, in which:
(A) of
(A), (B) and (C) of
(A), (B) and (C) of
(A) of
The plate 18 of the acoustic structure 10 has opening portions 21-i (i=1-6) formed therein. Each of the opening portions 21-i (i=1-6) in the plate 18 functions to communicate the interior hollow region 22-i, surrounded or defined by the plates 18, 19, 11-i, 11-(i+1), 20 and 23, with an acoustic space that is a room space where the acoustic structure 10 is installed. Further, sound absorbing members 30-m (m=1-7) are fixedly attached, e.g. by adhesive, to desired positions of a surface of the plate 18 opposite from the interior hollow regions 22-i (i=1-6), i.e. an outer surface which sound waves fall on (hereinafter referred to as “reflective surface ref”). Functions of the sound absorbing members 30-m will be detailed later.
The acoustic structure 10 is installed on an inner wall or ceiling of the acoustic space with the plate 18, having the opening portions 21-i (i=1-6) formed therein, oriented toward the middle of the acoustic space. The acoustic structure 10 thus installed with plate 18 oriented toward the middle of the acoustic space produces sound absorbing and sound scattering effects, so that it dissipates acoustic energy of sound waves propagated from the acoustic space toward the acoustic structure 10. The following explain basic principles on which the acoustic structure 10 produces the sound absorbing and sound scattering effects.
As shown in a sectional view of
Then, in the acoustic tube CLP-a, resonance occurs at a resonance frequency fan (n=1, 2, . . . ) represented by mathematical expression (1) below, and the traveling waves and reflected waves are combined together in the acoustic tube CLP-a into standing waves having a particle velocity node at the closed end of the acoustic tube CLP-a and a particle velocity antinode at the open end of the acoustic tube CLP-a. Further, in the acoustic tube CLP-b, resonance occurs at a resonance frequency fbn (n=1, 2, . . . ) represented by mathematical expression (2) below, and the traveling waves and reflected waves are combined together in the acoustic tube CLP-b into standing waves having a particle velocity node at the closed end of the acoustic tube CLP-b and a particle velocity antinode at the open end of the acoustic tube CLP-b. In mathematical expression (1) and mathematical expression (2) below, La indicates a length of the acoustic tube CLP-a (i.e., length from the left end of the interior hollow region 22-i to the opening portion 21-i), Lb indicates a length of the acoustic tube CLP-b (i.e., length from the right end of the interior hollow region 22-i to the opening portion 21-i), c represents a propagation velocity of the sound waves, and n represents an integer equal to or greater than 1 (one).
fan=(2n−1)·(c/(4·La))(n=1,2, . . . ) (1)
fbn=(2n−1)·(c/(4·Lb))(n=1,2, . . . ) (2)
Now consider a component of the resonance frequency fan of sound waves falling from the acoustic space in the opening portion 21-i and on a region of the reflective surface ref (i.e., surface of the plate 18 opposite from the interior hollow region 22-i) near the opening portion 21-i. Sound waves reflected off the closed end of the acoustic tube CLP-a and then radiated through the opening portion 21-i to the acoustic space are opposite in phase to sound waves falling from the acoustic space in the opening portion 21-i. On the other hand, sound waves falling from the acoustic space on a region of the reflective surface ref near the opening portion 21-i are reflected without involving phase rotation.
Thus, as shown in
Further, in frequency bands near each of the resonance frequencies fan and fbn, the phase of the sound waves radiated from the opening portion 21-i to the acoustic space and the phase of the sound waves reflected from the reflective surface ref to the acoustic space will assume near-opposite-phase relationship even when the sound waves are deviated from the resonance frequency fan or fbn, as long as the sound waves are close in frequency to resonance frequency fan or fbn to some degree. Thus, in frequency bands near each of the resonance frequencies fan and fbn, there are produced sound absorbing and sound scattering effects of degrees corresponding to closeness in frequency to the resonance frequency fan or fbn.
The foregoing are details of the basic principles of the sound absorbing and sound scattering effects. As set forth, although such sound absorbing and sound scattering effects are also producible or achievable for sound waves of high frequency bands, the sound absorbing and sound scattering effects producible for sound waves of high frequency bands are smaller (or lower in degree) than those producible for sound waves of low frequency bands. The sound absorbing members 30-m (m=1-7) shown in
Condition (a): Individual positions to which the plurality of sound absorbing members 30-m (m=1-7) are attached should be on regions of the reflective surface ref of the plate 18 other than neighborhoods of the opening portions 21-i (i=1-6). More specifically, the sound absorbing members 30-m (m=1-7) should be attached to positions outside (or surrounding) the respective neighborhoods of the opening portions 21-i (i=1-6) in such a manner that the sound scattering area is produced around each of the opening portions 21-i.
Condition (b): Individual positions to which the plurality of sound absorbing members 30-m (m=1-7) are attached should be dispersed in such a manner that the absorbing members 30-m (m=1-7) are spaced from one another by sufficient distances.
According to the instant embodiment, as set forth above, once sound waves of high frequency bands, for which sound absorbing and sound scattering effects are difficult to occur, fall on the plate 18 having the opening portions 21-i (i=1-6) and reflective surface ref, the incident sound waves are absorbed by the sound absorbing members 30-m (m=1-7) attached to the reflective surface ref. Thus, the instant embodiment can reliably prevent occurrence of acoustic inconveniences, such as booming and flatter echoes, for sound waves of wide frequency bands from low to high frequency bands. As noted above, the sound absorbing members are each formed of a material of which the absolute value |ζ| of the specific acoustic impedance ratio is equal to or smaller than 1 (one)
Further, in the instant embodiment, the sound absorbing members 30-m (m=1-7) are attached to regions of the reflective surface ref other than the neighborhoods of the opening portions 21-i (i=1-6). Thus, radiation of reflected sound waves having the same phase as incident sound waves from the neighborhoods of the opening portions 21-i (i=1-6) formed in the reflective surface ref can be prevented from being disturbed by the sound absorbing members 30-m (m=1-7). Thus, the instant embodiment can produce generally the same sound absorbing and sound scattering effects as in a case where no such sound absorbing member is attached to the reflective surface ref.
Furthermore, in the instant embodiment, as set forth above, the sound absorbing members 30-m (m=1-7) are in the form of a plurality of small pieces attached to the reflective surface ref in such a manner that the sound absorbing members 30-m (m=1-7) are dispersed to be spaced from one another by sufficient distances. Sound waves reflected off points around the individual sound absorbing members 30-m (m=1-7) on the reflective surface ref fall on the sound absorbing members 30-m (m=1-7) because of diffraction succeeding the reflection, so that they are absorbed by the sound absorbing members 30-m (m=1-7). In this manner, the instant embodiment can enhance a sound absorbing coefficient per unit area as compared to a case where sound absorbing members 30-m (m=1-7) are attached collectively to a single place on the reflective surface ref.
(A) of
(A) of
Further, in the acoustic structure 10C, the plate 58 has a plurality of opening portions 73-k (k=1-9), of which the opening portions 73-1, 73-2, 73-3, 73-5, 73-6, 73-7, 73-8 and 73-9 each have a square shape having vertical and horizontal dimensions each equal to the distance D3 between the plates 62 and 64. Further, the opening portion 73-4 has a rectangular shape having a vertical dimension equal to the distance D3 between the plates 62 and 64 and a horizontal dimension equal to the distance D1 between the plates 20 and 21.
The opening portion 73-1 functions to communicate the interior hollow region 72-1, surrounded or defined by the walls 58, 59, 60, 61, 62 and 64, with the external acoustic space, and the opening portion 73-2 functions to communicate the interior hollow region 72-2, surrounded or defined by the walls 58, 59, 60, 64, 65 and 69, with the external acoustic space. Further, the opening portion 73-3 functions to communicate the interior hollow region 72-3, surrounded or defined by the walls 58, 59, 61, 64, 65 and 69, with the external acoustic space, and the opening portion 73-5 functions to communicate the interior hollow region 72-5, surrounded or defined by the walls 58, 59, 60, 66, 67 and 70, with the external acoustic space. Furthermore, the opening portion 73-6 functions to communicate the interior hollow region 72-6, surrounded or defined by the walls 58, 59, 61, 66, 67 and 70, with the external acoustic space, and the opening portion 73-7 functions to communicate the interior hollow region 72-7, surrounded or defined by the walls 58, 59, 60, 67, 68 and 71, with the external acoustic space. Furthermore, the opening portion 73-8 functions to communicate the interior hollow region 72-8, surrounded or defined by the walls 58, 59, 61, 67, 68 and 71, with the external acoustic space, and the opening portion 73-9 functions to communicate the interior hollow region 72-9, surrounded or defined by the walls 58, 59, 60, 61, 63 and68, with the external acoustic space. In addition, the opening portion 73-4 functions to communicate the interior hollow region 72-4, surrounded or defined by the walls 58, 59, 60, 61, 65 and 66, with the external acoustic space. The interior hollow region 72-4 located inwardly of the opening portion 73-4 is loaded with the sound absorbing member 80, and this sound absorbing member 80 has a portion exposed to the external acoustic space through the opening portion 73-4. The portion of the sound absorbing member 80 exposed through the opening portion 73-4 lies in flush with the plate 58 having the opening portion 73-4 formed therein. The foregoing are the details of the construction of the acoustic structure 10C.
In the acoustic structure 10C constructed in the above-described manner, the opening portions 73-1-73-3 and 73-5-73-7, where the sound absorbing member 80 is not provided, each function to form a sound absorbing area similarly to the opening portion 21-i shown in
In the instant embodiment of the acoustic structure 10C, no sound absorbing member is attached to the plate 58; instead, the sound absorbing member 80 is loaded in one (i.e., hollow region 72-4) of the nine interior hollow regions 72-k (k=1-9). The sound absorbing member 80 is partly exposed to the external acoustic space through the opening portion 73-4. Thus, this acoustic structure 10C can be formed in a uniform thickness in its entirety and can reliably avoid the problem that occurrence of sound absorbing and sound scattering effects is prevented due to coming-off or detachment, from the plate 58, of the sound absorbing member.
Whereas the foregoing have described some preferred embodiments of the present invention, various other embodiments and modifications are also possible as exemplified below.
(1) In the above-described first to third embodiments of the acoustic structure 10, 10A and 10B, the number of the interior hollow regions 22-i may be seven or more, or five or less, and the interior hollow regions 22-i may differ from one another in horizontal dimension or width.
(2) Further, in the above-described first to third embodiments 10, 10A and 10B, the sound absorbing members 30-m (m=1-7), 31, 32, 33, 34, 35, 36 and 37 may be formed of any other suitable material than a porous material.
(3) Further, in the above-described first to third embodiments, each of the interior hollow regions 22-i may be surrounded or defined by five or less plates, or by seven or more plates.
(4) Further, in the above-described third embodiment (acoustic structure 10B), each of the opening portions 21-i has a square shape, and the region of the reflective surface ref which is located in the neighborhood of each of the opening portions 21-i and in which the absorbing member 38 is not attached (i.e., non-sound-absorbing-member-attached region in the neighborhood of the opening portions 21-i) has a square shape slightly larger than the opening portions 21-i. As a modification, the opening portions 21-i and the non-sound-absorbing-member-attached regions in the neighborhoods of the opening portions may each be of any other desired shape than a square shape, such as a true circular shape or a substantial square shape with four arcuately curved corners. In such a case, the non-sound-absorbing-member-attached regions AR in the neighborhoods of the opening portions 21-i, as shown in
(5) In each of the above-described first to third embodiments of the acoustic structure 10, 10A and 10B, an area So of a section, parallel to the plate 18, of at least one (e.g., opening portion 21-1) of the opening portions 21-i (i=1-6) (i.e., area of the opening portion 21-1) may be made smaller than an area Sp of a section, perpendicularly intersecting the plate 18, of the interior hollow region 22-1 (i.e., cross-sectional area Sp of the interior hollow region 22-1). This is because such an acoustic structure 10D where the area So is smaller than the area Sp can produce sound absorbing and sound scattering effects over even wider frequency bands.
The reason why the acoustic structure 10D with the area So smaller than the area Sp can produce sound absorbing and sound scattering effects over even wider frequency bands is as follows. As set forth above, the sound absorbing effect is an effect produced by the phase of sound waves radiated from the opening portion 21-i to the acoustic space and the phase of sound waves reflected off the reflective surface ref to the acoustic space assume near-opposite-phase relationship when sound waves of the resonance frequencies fan and fbn of the acoustic pipes CLP-a and CLP-b and frequencies near the resonance frequencies fan and fbn have fallen in the acoustic structure 10. Thus, the wider the frequency bands over which sound waves falling in the acoustic structure 10 through the opening portion 21-i and reflected sound waves reflected through the opening portion 21-i toward a direction of incidence of the sound waves assume near-opposite-phase relationship, the wider should become the frequency bands over which the sound absorbing effect can occur.
In this case, an amplitude and phase of sound waves reflected in the direction of incidence from a boundary surface bsur between a first medium (e.g., air within the opening portion 21-i or a rigid material forming the acoustic structure 10) and a second medium (e.g., air within the acoustic structure 10) when sound waves have fallen from the second medium vertically toward the first medium depend on a specific acoustic impedance ratio ζ (ζ=r+jx:r=Re(ζ), x=Im(ζ)) of the boundary surface bsur. More specifically, if the absolute value |ζ| of the specific acoustic impedance ratio of the boundary surface bsur is less than 1 (one), reflected waves having a phase difference within ±180 degrees from the sound waves falling on the boundary surface bsur are radiated from the boundary surface bsur. If Im(ζ)>0, the smaller the absolute value |Im(ζ)| of an imaginary part Im of the specific acoustic impedance ratio ζ, the closer the phase difference approaches +180 degrees. Further, if Im(ζ)<0, the smaller the absolute value |Im(ζ)| of the imaginary part Im of the specific acoustic impedance ratio ζ, the closer the phase difference approaches −180 degrees.
If a comparison is made between a frequency characteristic of the imaginary part Im of the specific acoustic impedance ratio ζ when a ratio rs between the area So of the section of the opening portion 21-i and the area Sp of the section of the hollow region 22-i (rs=So/Sp) is greater than 1 (i.e., So>Sp) and a frequency characteristic of the imaginary part Im of the specific acoustic impedance ratio ζ when the ratio rs is smaller than 1 (i.e., So<Sp), it can be seen that frequency bands over which the imaginary part Im of the frequency characteristic is equal to or smaller than a given value (e.g., Im(ζ)=1) are wider in the former case than in the latter case (see Japanese Patent Application Laid-open Publication No. 2010-84509 (patent literature 2, and particularly FIG. 9 thereof) for details of the relationship between the ratio rs and frequency characteristic of the imaginary part Im). Thus, the smaller than the area Sp the area So is, the wider become the frequency bands over which reflected sound waves having a phase difference, nearly the opposite phase, from sound waves entering or falling in the opening portion 21-i can be radiated through the opening portion 21-i. For the foregoing reason, the acoustic structure with the area So smaller than the area Sp can produce sound absorbing and sound scattering effects over even wider frequency bands.
(6) In the above-described fourth embodiment of the acoustic structure 10C, the number of the interior hollow regions 72-k may be any one of 2 to 8, and 10 and more. Further, whereas the fourth embodiment has been described above in relation to the case where the interior hollow region 72-4 having the sound absorbing member 80 loaded therein has the same width as the other interior hollow regions 72-1-72-3 and 72-5-72-9, the interior hollow region 72-4 may have a different width from the other interior hollow regions 72-1-72-3 and 72-5-72-9. As another modification, the opening portion 73-4, which functions to communicate the interior hollow region 72-4 with the outside, may have a width D7 in the left-right direction smaller than the width D1, in the left-right direction, of the interior hollow region 72-4. In such a case, the sound absorbing member 80 may be loaded only in a space of the interior hollow region 72-4 immediately under the opening portion 73-4 so that closed spaces are formed to the left and right of the sound absorbing member 80 within the interior hollow region 72-4. As a further modification, the sound absorbing member may be loaded in two or more interior hollow regions 72.
(7) In the above-described fourth embodiment, the sound absorbing member 80 may be formed of any other suitable material than a porous material.
(8) Further, whereas the fourth embodiment has been described above in relation to the case where the interior hollow region 72-4 for loading therein the sound absorbing member 80 has a shape elongated in the left-right direction, the interior hollow region 72-4 may have a shape elongated in the front-rear direction or in an oblique direction, or may be of a combination of such shapes.
(9) As a further embodiment of the present invention, a door may be provided which has, on its one surface or opposite surfaces, the above-described fourth embodiment of the acoustic structure 10C.
The present application is based on, and claims priorities to, JP PA. 2010-113690 filed on May 17, 2010 and JP PA. 2010-279660 filed on Dec. 15, 2010. The disclosure of the priority applications, in its entirety, including the drawings, claims, and the specification thereof, is incorporated herein by reference.
Number | Date | Country | Kind |
---|---|---|---|
2010-113690 | May 2010 | JP | national |
2010-279660 | Dec 2010 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
2350513 | Leadbetter | Jun 1944 | A |
2887173 | Boschi | May 1959 | A |
2989136 | Wohlberg | Jun 1961 | A |
4821841 | Woodward et al. | Apr 1989 | A |
4989688 | Nelson | Feb 1991 | A |
6021612 | Dunn et al. | Feb 2000 | A |
6892856 | Takahashi et al. | May 2005 | B2 |
20020017426 | Takahashi et al. | Feb 2002 | A1 |
20050167193 | Van Reeth | Aug 2005 | A1 |
20060059801 | Allaei | Mar 2006 | A1 |
20100065369 | Honji | Mar 2010 | A1 |
Number | Date | Country |
---|---|---|
101404159 | Apr 2009 | CN |
803835 | Nov 1958 | GB |
2002-30744 | Jan 2002 | JP |
2010-84509 | Apr 2010 | JP |
Entry |
---|
Extended European Search Report dated Dec. 2, 2011 (six (6) pages). |
Chinese Office Action dated Jun. 12, 2012, including English translation (eleven (11) pages). |
Chinese Office Action with English translation dated Nov. 22, 2012 (sixteen (16) pages). |
Chinese Office Action dated Apr. 3, 2013 w/ English Translation (eleven (11) pages). |
Number | Date | Country | |
---|---|---|---|
20110278091 A1 | Nov 2011 | US |