Search Images Maps Play YouTube News Gmail Drive More »
Sign in
Screen reader users: click this link for accessible mode. Accessible mode has the same essential features but works better with your reader.


  1. Advanced Patent Search
Publication numberUS3180448 A
Publication typeGrant
Publication dateApr 27, 1965
Filing dateJan 2, 1962
Priority dateJan 2, 1962
Publication numberUS 3180448 A, US 3180448A, US-A-3180448, US3180448 A, US3180448A
InventorsGary Jr Wright W, Jones Jolm S, Nadler Max A
Original AssigneeAerojet General Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Laminated acoustic panel with sound absorbing cavities
US 3180448 A
Abstract  available in
Previous page
Next page
Claims  available in
Description  (OCR text may contain errors)

A ril 27, 1965 w. w. GARY, JR., ETAL 8 LAMINATED ACOUSTIC PANEL WITH SOUND ABSORBING CAVITIES Filed Jan. 2, 1962 INVENTOR. WRIGHT w. GARY JR. LIONEL ISENBEFQG BY JOHN S. JONES MAX A. NADLE ETTORNEE United States Patent 3,180,448 LAMINATED ACOUSTIC PANEL WITH SOUND ABSORBING CAVITIES Wright W. Gary, Jr., Arcadia, Lionel Isenberg, Downey, John S. Jones, La Habra, and Max A. Nadler,.Glendora, Calif., assignors to Aerojet-General Corporation, Azusa, Calif., a corporation of Ohio Filed Jan. 2, 1962, Ser. No. 163,484 1 Claim. (Cl. 18133) This invention relates to sound proofing and more particularly to an acoustic damping panel.

Heretofore, acoustic damping panels were formed from porous materials or from panels into which a large number of holes were drilled. The sound absorbing characteristics of a panel formed from porous material are not completely satisfactory because the panel is a less efficient sound absorber at higher frequencies where noise is most objectionable. Other sound absorbing panels have small holes drilled therein and these holes help the panel to more efiiciently absorb certain frequencies which depend on the dimensions of the holes. These holes may cause the panels to act as a reflector rather than a sound absorber for other frequencies.

Many of these difficulties could be avoided if a conventional acoustic panel could be made larger in order to provide a greater sound absorbing area. However, space limitations often make this impossible.

What is needed, therefore, and comprises an important object of this invention is to provide an acoustic damping panel which has a substantially greater sound absorbing surface area than the external dimensions of the panel and which is designed so it can efliciently absorb sound frequencies above any predetermined frequency so that the objectionable higher noise frequencies can be absorbed or attenuated.

The invention, in its broadest aspect, comprises forming an acoustic panel from a plurality of strips of sound absorbing material secured together. Certain of these strips are formed with holes or openings extending therethrough. These holes are shaped so that when the strips are secured together to form the laminated panel, the holes which are in alignment with each other cooperate to form enlarged cavities in the panel. If these cavities are Helmholtz cavities, they effectively absorb or attenuate sound at frequencies above the resonating frequency of the cavity as determined by the dimensions of the cavity. With this arrangement, sound will be more efiiciently attenuated and absorbed both by the greater surface area of the panel provided by the inner walls of the cavities and by the absorption or attenuation of sound at frequencies above the resonant frequency of the cavity.

This and other objects of this invention will become more apparent when read in the light of the accompanying drawings and specification wherein:

FIG. 1 is a side sectional view of the new and improved acoustic panel constructed according to the principles of this invention;

FIG. 2 is an exploded side sectional view of the acoustic 3,180,448 Patented Apr. 27, 1965 ice acoustic panel indicated generally by the reference numeral 10 is composed of a plurality of strips laminated together by any suitable means. These strips include an inner perforate strip 12, an outer imperforate or base strip 14 and a series of intermediate strips 16, 18, and 20 which both connect the inner and outer strips together, and, as described below, serve to absorb and attenuate sound frequencies above any predetermined frequency. As will become apparent below, the number of intermediate srtips can be varied as desired.

As best seen in FIGURE 2, the inner perforate strip 12 and the series of intermediate strips 16, 18, and 20, are all provided with openings 22, 24, 26, and 28 extending therethrough. These openings have varying sizes and shapes and in the particular embodiment shown, the openings in each strip are shaped so they are generally similar to a particular segment or section of a Helmholtz resonating cavity.

With this arrangement, when the strips are secured together, openings 22, 24, 26, and 28 in each strip cooperate with each other to form typical Helmholtz cavities in the panel. The imperforate or base strip 14 closes ofi one end of the cavity and the perforations 22 in the inner strip 12 serve as mouths for the cavities. The mouths 22 extend inward from surface 15 of strip 12 and are small in comparison to the width of the cavities. In the embodiment shown, there are two different sized openings in each strip. Consequently, when the strips are assembled together, the acoustic panel in this particular embodiment will have two differently shaped Helmholtz cavities 30 and 32 formed therein for reasons to become apparent below. It is apparent that this method of forming the acoustic panel permits any number of differently shaped cavities to be formed in an acoustic panel, using simple, inexpensive, and conventional tools.

The strips are all made of sound absorbing material such as a cellulose board. Consequently, the inner surfaces of cavities 30 and 32 serve to absorb and attenuate sound. As a result, the total sound absorbing surface of the panel 10 is substantially greater than the external dimensions of the panel.

In addition, the Helmholtz cavities resonate and consequently absorb sound frequencies at the fundamental frequency of the cavity, which is primarily determined by the volume of the cavity and the size of the mouth 22. Helmholtz cavities also have additional resonant or sound absorbing frequencies which are higher than the fundamental resonant frequency and are not harmonically related to the fundamental resonant frequency. These higher or additional resonant frequencies are determined by the shape of the cavity rather than the volume. Consequently, by a judicious selection of the shapes of the holes in the various strips, the panel can be provided with differently shaped Helmholtz resonating cavities. With this arrangement, and acoustical panel can be designed to absorb sound in two ways. First, the sound may be absorbed by the impact of the sound waves on the sound absorbing material of the panel, and second, the sound may be absorbed at the varying fundamental resonant frequencies of the differently shaped Helmholtz cavities in the panel and at their more numerous additional resonant frequencies. In addition, by forming the acoustic panel this way, its inner surface 15 will be smooth and generally planar. Consequently, from the point of view of appearance, the acoustic panel will be just as satisfactory as prior perforate panels.

The modified acoustic panel, indicated generally by the reference numeral 40 in FIGURE 3, shows how acoustic panels having internal cavities with other shapes can be easily fabricated. In this modification, the emphasis is on presenting a sound absorbing surface to the incident sound Q which is substantially greater than the external dimensions of the panel. As shown in FIGURE 3, acoustic panel 40 is composed of an inner perforate strip 44, an outer imperforate strip. 46, and a single intermediate strip 48. As seen in FIGURES 3 and 4, the inner strip 44 is provided with perforations 5t extending therethrough, the intermediate strip 43 is providedwith enlargedcircular openings 52 extending therethrough, as shownin FIGI 5, and the outer or base strip 4a is imperforate, as shown in FIG. 6.

With this arrangement, when the strips are laminated together and openings 50 and 52 are arranged so that they are concentric with each other, the combination of these strips forms an acoustic panel with a plurality of enlarged internal cavities 42 therein. It is apparent from inspection of FIG. 3 that the inner surface areas of the cavities 42 provide the panel with a sound absorbing area which is substantially greater than the area defined by the external dimensions of the panel. In addition, it is apparent that the openings 56) and 52 can be easily drilled in strips 44 and 48. Consequently, the fabrication of this new and more efficient acoustical panel 40 is simple and economical.

It is to be understood that the forms of the invention herewith shown and described are to be taken as preferred comprising an imperforate strip, a second. strip having truncated frusto-conical holes therethrough provided with small openings closed off by said imperforate strip and g with large openings, a third strip having large cylindrical holes therethrough communicating with the large openings, a fourth strip having truncated frusto-conical holes therethrough provided with large openings communicating with the cylindrical holes and with small openings, and a fifth strip having small cylindrical holes communicating with the fourth strip small openings, the holes being aligned to form thecavities.

References Cited by the Examiner UNITED STATES PATENTS OTHER REFERENCES I Vol. 19, No. 6, "pages 972-981, November 1947, The

Application of Helmholtz Resonators toSound-Absorbing Structures, The Journal of the Acoustical Society of America. 7

LEO SMILOW, Prima ry Examiner.

ARNOLD 'RUEGG, Examiner.

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US1937889 *Oct 6, 1931Dec 5, 1933Clark Howard ThomasSound absorbing material
US2089492 *Jul 6, 1935Aug 10, 1937American Radiator CoDuct
US2840179 *Jun 17, 1954Jun 24, 1958Junger Miguel CSound-absorbing panels
US2984312 *Apr 24, 1959May 16, 1961Owens Corning Fiberglass CorpAcoustical wall board
GB776994A * Title not available
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3819009 *Feb 1, 1973Jun 25, 1974Gen ElectricDuct wall acoustic treatment
US3831710 *Jan 24, 1973Aug 27, 1974Lockheed Aircraft CorpSound absorbing panel
US3913702 *Apr 8, 1974Oct 21, 1975Lockheed Aircraft CorpCellular sound absorptive structure
US4084367 *Jan 24, 1977Apr 18, 1978Haworth Mfg., Inc.Sound absorbing panel
US4141433 *Jun 4, 1976Feb 27, 1979Lord CorporationSound absorbing structure
US4243117 *Oct 27, 1978Jan 6, 1981Lord CorporationSound absorbing structure
US4291080 *Mar 31, 1980Sep 22, 1981Vought CorporationSound attenuating structural panel
US4339018 *May 19, 1980Jul 13, 1982Lord CorporationSound absorbing structure
US4860506 *Mar 4, 1988Aug 29, 1989Daiken Trade & Industry Co., Ltd.Floor panel for floating floor
US6244378Dec 11, 1998Jun 12, 2001Owens Corning Fiberglas Technology, Inc.Dual sonic character acoustic panel and systems for use thereof
US6789645Jun 18, 1999Sep 14, 2004The Dow Chemical CompanySound-insulating sandwich element
US6977109 *Mar 28, 2000Dec 20, 20053M Innovative Properties CompanyMicroperforated polymeric film for sound absorption and sound absorber using same
US7731878Dec 17, 2004Jun 8, 20103M Innovative Properties CompanyProcess of forming a microperforated polymeric film for sound absorption
US20050104245 *Dec 17, 2004May 19, 20053M.Innovative Properties CompanyProcess of forming a microperforated polymeric film for sound absorption
US20070193175 *Feb 21, 2006Aug 23, 2007Ta-Chung HaoStructure of decoration acoustic board
WO2000034595A1 *Dec 3, 1999Jun 15, 2000Owens CorningDual sonic character acoustic panel and systems for use thereof
U.S. Classification181/290, 52/144
International ClassificationE04B1/86, E04B1/84
Cooperative ClassificationE04B1/86, E04B2001/8485, E04B2001/8461
European ClassificationE04B1/86