The present invention relates to acoustical room treatments, and more specifically relates to a tunable acoustic panel that functions as an acoustic diffuser and absorber, the method for the production thereof, and a method of selectively varying the acoustical response of a room or performance space.
For indoor rooms intended primarily for listening to music, whether residential rooms used for watching television or listening to recorded music, or public auditoriums or enclosures employed for listening to live music, it is desired that the quality of the heard sound be as accurate as the produced sound.
It is well known that rooms can produce distortional acoustic effects such as echoes, reverberations, amplified bass tones, and uneven volume distribution throughout the room. Systems for improving the sound quality of indoor rooms have been disclosed in U.S. Pat. Nos. 3,049,190; 3,411,605; 3,590,354; 4,226,299; 4,605,088; 4,682,670; 5,035,298; 5,896,710; 6,530,451; 6,782,971, all being incorporated herein by reference. Such prior systems generally employ large volume panels that attach to the walls or employ floor-standing structures, some of which are movable or adjustable nature. Such panels and related structures are usually of bulky, heavy and expensive construction, or difficult to install, or detract from the aesthetic appearance or floor space of the room. The prior art systems did not address the needs for performance areas such as college recital halls or school cafetoriums areas where variable acoustics are often required. Moreover, past systems have not adequately addressed the problem that the same room or performance space is often used for different purposes that present different acoustic challenges.
Present day music rooms are usually shared between different type of bands (jazz and concert), orchestras (wind ensembles and string ensembles), and choirs (vocal and jazz) with the acoustics being a compromise between these various uses. A homemade solution to this problem is an acoustic panel th at folds out for absorption and folds in for diffusion. Retractable curtains are also commonly used, but very seldom work effectively. For the performing arts market, motorized banners are used to vary acoustics. One limitation of the prior art devices is that modifying the acoustic character of a room requires considerable time and manpower or are complex to operate.
It is accordingly an object of the present invention to provide a device that has a quick and simple modification of its acoustic diffusion and absorption properties. It is a further object of this invention to provide a method modifying of a room's acoustic character by using a tunable acoustic panel. It is also an object of this invention to provide a method of making a tunable acoustic device that can be tuned with a single mechanical movement. It is yet another object of this invention to provide a kit and instructions that optimizes the shipping of a tunable acoustic panel yet allows for simple assembly of its component parts.
The purpose of the present invention is to provide the ability to quickly and easily increase or decrease reverberation in a rehearsal or performance room. The tunable acoustic panel enables a rehearsal room to be satisfactorily used for both instrumental and choral rehearsal. Instrumental groups prefer a more absorbent environment (0.8 seconds of reverberation time) while choral groups prefer more reverberation (up to 1.5 seconds). Prior art devices do not provide this type of flexibility in an acoustical panel system.
The invention enables the changing of a room's acoustic characteristics between absorption to diffusion by one person, presents an aesthetically pleasing finish, provides a broad range of frequency absorption, is competitively priced with fixed acoustic panels, and is easy to install.
Embodiments of the present invention are directed to an acoustic panel with an internal mechanism to open and close a diaphragm or bellows-type structure. The acoustic panel is fronted by a micro-perforated face sheet of steel that has both sound diffusion and absorption characteristics. The opening or closing of the diaphragm changes the distance between the diaphragm and the micro-perforated face sheet, which changes the sound diffusion/absorption characteristics of the panel. The acoustic panel of embodiments of the present invention has its maximum sound absorption quality when the diaphragm is completely closed. Conversely, the acoustic panel would have its maximum sound diffusion quality when the diaphragm is fully open, as it provides a hard curved surface to diffuse sound waves.
In one representative embodiment the micro-perforated face sheet is steel, which provides a durable surface and maintains the shape and size of the micro-perforated holes. The face sheet can also be constructed of plastic or other durable material. For both aesthetics and sound absorption, the face sheet may be covered with fabric. Numerous fabrics can be used to modify both acoustic and aesthetic properties of the panel. The face material can be made of more durable and stable materials to withstand impact and denting that is expected in school and performing arts environments.
The micro-perforated panel is curved to provide proper diffusion. The panel uses the air space behind the face panel for absorption and the preferred embodiment has been increased to a 12 inch depth, and to gain more absorption. In addition, the overall square footage of the panel is increased from the 18 square feet of conventional panels, to 32 square feet, to provide the necessary absorption.
In another representative embodiment, the diaphragm is opened and closed via a rotating actuator that runs the vertical length of the acoustic panel. The rotating actuator could also run transversely across the width of the acoustic panel or more than one rotating actuator could be used in a single acoustic panel. Further, the rotating actuator does not have to run the entire length of the acoustic panel; it merely needs to function to open and close the diaphragm. The actuator can be made of metal, plastic, or any durable material with enough stiffness to open and close the diaphragm through numerous cycles.
In yet another embodiment, the diaphragm or bellows-type structure is comprised of two plastic sheets that are hinged on their sides to hold them together with the actuator lying between them.
In another representative embodiment, the rotating actuator is operated by a lever that is accessible on the exterior of the fully-assembled acoustic panel. The lever may also include a handle to assist in moving the lever to rotate the actuator. The handle may be provided with an indicator position that is labeled ABSORPTION or DIFFUSION.
The tunable acoustic panel of the present invention is designed to acoustically impact the range of frequencies from 125 Hz to 4,000 Hz. For a typically-sized rehearsal space, the amount of variability in changing the reverberation time ranges from 0.5 to 0.8 seconds. An embodiment of the present invention is an acoustic panel that is 48 inches by 48 inches and can be stacked to create a 48 inch by 96 inch acoustic panel that can be operated by a single lever. Using a stackable configuration makes installation of the tunable acoustic panels easier and safer.
In yet another representative embodiment of the present invention, the acoustic panel is shipped in a box with the panels of the diaphragm pre-installed into the tray of the panel with other components nested in molded cavities of the tray. Side-panel extrusions are attached at each end to top and bottom frame extrusions. The frame drops into the tray and snaps into place without fasteners. The lever is attached to the actuator and top and bottom finish panels are attached from the inside of the panel to cover the frame extrusion. Trim plates can be added for aesthetics and an actuator handle can be attached to the actuator lever. Mounting brackets are installed with appropriate spacing on the wall or other surface that will house the panel. The panel is then attached to the brackets to hold the panel in place. The micro-perforated panel is then installed on the front of the unit between the side-panel extrusions. Fabric is then installed to cover the micro-perforated panel and side-panel extrusions to complete the assembly and installation of the acoustic panel.
In another representative embodiment, multiple tunable acoustic panels as described herein are used in combination with panels that act only as acoustic diffusers or acoustic absorbers (i.e., panels that do not include an internal diaphragm or bellows-type structure) to provide a range of acoustic environments for a room that can be altered by simply adjusting the tunable panels to each diffuse or absorb acoustics. Currently available ceiling diffuser panels may be used in conjunction with the tunable and fixed acoustic wall panels to provide desired ceiling diffusion for the room.
A further embodiment of the invention is a method of making a room acoustically tunable by using a combination of tunable acoustic panels, panels that act only as acoustic diffusers or acoustic absorbers, and ceiling acoustic panels. The method includes determining the acoustic requirements of a room and modeling the acoustics of the room. The method further includes obtaining information from the owner of the room via a questionnaire. The questionnaire is designed to obtain not only the physical description of the room (dimensions and materials of construction), but the primary and secondary uses of the room (orchestra, band, choral, theater). The questionnaire used in this method also seeks use information such as the number of students that may use the room at a given time, the finishes of the room, they types of furniture in the room (storage cabinets, risers, staging). The information collected is used to acoustically model the room and determine the appropriate number of tunable acoustic and fixed acoustic panels as well as spacing requirements to optimize the acoustics for the various uses.
The above summary of the various representative embodiments of the invention is not intended to describe each illustrated embodiment or every implementation of the invention. Rather, the embodiments are chosen and described so that others skilled in the art can appreciate and understand the principles and practices of the invention.
A tunable acoustic panel according to an embodiment is depicted generally in
Referring to
Referring to
In the preferred embodiment, end panels 170 are affixed to the back panel 150 and side panels 160 by screws (not shown) to add rigidity to the tunable acoustic panel 100 and to allow for mounting of an actuator assembly 300. End panels 170 may also be affixed to the back panel 150 and side panels 160 by adhesives, bolts, or other fastening mechanisms known in the art. End panels 170 include actuator rod mounts 175 to accept the ends of the actuator rod 310 of the actuator assembly 300. In the preferred embodiment actuator rod mounts 175 are an orifice that accepts a bearing 178 of appropriate size to receive the actuator rod 310.
Referring to
In one embodiment, the expandable acoustic diaphragm 130 is constructed of two actuator panels 135 joined together along most of the length of their side edges by hinges 140 (
The embodiments above are intended to be illustrative and not limiting. Additional embodiments are within the claims. In addition, although embodiments of the invention have been described with reference to particular embodiments, those skilled in the art will recognize that changes can be made in form and detail without departing from the spirit and scope of the invention.
This application claims the benefit of U.S. Provisional Application No. 61/828,261, filed May 29, 2013, which is hereby fully incorporated herein by reference.
Number | Date | Country | |
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61828261 | May 2013 | US |