The present invention relates to a combination light diffuser and acoustical treatment and listening room including such fixtures. Air diffusers provide uniform temperature and prevent cold and hot zones. Lighting diffusers uniformly illuminate a room removing optical glare and minimizing light and dark zones. Similarly, a sound diffuser uniformly distributes sound in a room, to provide ambiance, even coverage and removes acoustical glare caused by strong specular reflections. Sound can be controlled by absorption, reflection and diffusion. Sound is attenuated by absorption, redirected by reflection and uniformly distributed by diffusion. While the design of spaces used for speech has typically relied solely on absorption, an optimal design can only be achieved using an appropriate combination of each constituent.
Typical ceiling T-bar lighting units consist of an incandescent, fluorescent or LED light source with a flat or parabolic diffusing element. There are many applications, including classrooms, lecture halls, conference and meeting rooms where a ceiling lighting fixture that also provided sound diffusion or sound absorption would improve communication and speech intelligibility. The present invention solves this problem by teaching a novel approach by incorporating a sound diffusing or absorptive element at the face of the light source to simultaneously diffuse the light providing uniform illumination and sound control.
In the application of sound control acoustic treatments in the design of classrooms, training rooms, conference and meeting rooms, lecture halls, presentation rooms, or essentially any room where high speech intelligibility is required, the complete acoustical palette is considered. Typically the ceiling in a speech room consists of acoustical ceiling tile and lighting fixtures. Why is an absorptive ceiling not conducive to high intelligibility?
As is known, the ear/brain processor can fill in a substantial amount of missing information in music, but requires more detailed information for understanding speech. The speech power is delivered in the vowels (a, e, i, o, u and sometimes y) which are predominantly in the frequency range of 250 Hz to 500 Hz. The speech intelligibility is delivered in the consonants (b, c, d, f, h, j, k, I, m, n, p, q, s, t, v, w), which requires information in the 2,000 Hz to 4,000 Hz frequency range. People who suffer from noise induced hearing loss typically have a 4,000 Hz notch, which causes severe degradation of speech intelligibility.
This raises the question: Why would we want to absorb these important frequencies on the ceilings of speech rooms and prevent them from fusing with the direct sound, thereby making it softer and less intelligible? This appears to be the opposite of what is desirable.
Research has revealed the importance of early reflections and reverberation to intelligibility. There is a difference between hearing speech and understanding it. When early reflections arrive in a temporal window roughly 20-50 ms after the direct sound and roughly between 5 and 15 dB below the level of the direct sound, there is a process called temporal fusion in which the direct sound is fused with the early reflections making it louder and more intelligible. So one important design criterion for small rooms used for speech is to provide early reflections and to not absorb them!
Many of the problems that arise in poorly designed speech rooms stem from .a low Signal to Noise Ratio. The signal consists of the direct sound and early reflections (between roughly 20-50 ms). The noise consists of reverberation, occupant noise, exterior noise intrusion and noisy MEP systems. Adults typically require 0 dB signal-to-noise ratios for high speech intelligibility when listening to simple and familiar speech material for short periods of time. An additional 2 dB is needed to compensate for neurological immaturity. An additional 5 dB is required to compensate for sensorineural and conductive hearing losses. An additional 5 dB is required for limited English proficiency and language disorders. An additional 3 dB is required to compensate for the effects of excessive reverberation. These additional requirements for speech rooms total 15 dB over that of normal adults, or a signal-to-noise ratio of +15 dB. Passive acoustics in the architecture can be employed to provide some of this needed gain. Most design approaches only try to reduce the noise and often simultaneously decrease the strength of the signal as well, by using only absorption. The result is no net improvement. Excess reverberation can also corrupt the purity of the speech signal and decrease intelligibility. So it is important to increase the signal, by (1) introducing diffuse ceiling reflection, and (2) decreasing all forms of noise, including reverberation. At the same time, ceiling illumination is also required, but it is often located in locations where acoustical treatments should optimally be positioned. Hence, there is a need for combining sound diffusion and lighting, as well as sound absorption and lighting to reduce the reverberation time. It would be advantageous to place luminous absorptive fixtures around the perimeter of the room, to complement centrally located luminous diffusers. It is with these thoughts in mind that the present invention was developed.
The present invention relates to a combination light diffuser and acoustical treatment and listening room including such fixtures. The present invention includes the following interrelated objects, aspects and features:
(1) In accordance with the teachings of the present invention, the optimal approach is to treat the ceiling by decreasing the noise and simultaneously increasing the signal by providing:
(2)
(3) In
(4) In
(5) Since the ceiling is an important acoustical design element and space for lighting, the sound diffusion and absorption can be competitive, so it is advantageous to be able to combine these elements in a single lighting fixture element.
(6) The uniformity of sound diffusion is specified by the ISO 17497-1 and ISO 17497-2 standards. The absorption efficiency can be specified by ISO 354, in the form of the random incidence absorption coefficient, or ISO 10534-2, in the form of the normal incidence absorption coefficient. The lighting photometrics of the combined lighting fixture and light/sound diffuser/sound absorber are specified by the Illuminating Engineering Society in an IES photometrics file. Diffusive and absorptive elements used in combination with the lighting source should have good acoustical performance and not just be ornamental structures.
(7) Elements to diffuse light uniformly may be fabricated from plastic or metal, in flat form, cells or parabolic egg crate formats. Sound diffusing surfaces were first introduced by Applicant in the early 1980s and are fabricated from wood, plastic, metal, concrete and glass reinforced gypsum. The present invention simultaneously provides uniform lighting and sound control, by replacing a traditional lighting diffuser, with either a translucent sound diffuser or a translucent sound absorber.
(8) Sound diffusing surfaces, fabricated from translucent plastics, are used to replace conventional light diffusing elements in lighting fixtures and simultaneously diffuse light and sound. The sound diffusing ability is derived from the topology of the sound diffuser. There are many topologies that can scatter sound, from random surfaces to optimally designed topologies based on mathematical number theory sequences or boundary element optimization techniques. The deeper the light/sound diffuser is, the lower the frequencies that are efficiently scattered. The present invention includes ways to combine light and sound diffusion in the same lighting fixture. The combined luminous diffuser facing can be fabricated by thermoforming, injection molding or any appropriate plastic molding technology that allows sufficient light transmission from the preferred embodiment of an LED light source. If the diffusive facing is flush with the ceiling plane, it can be covered with a translucent and acoustically transparent non-woven mat to allow the light/sound diffuser to match the acoustical veil used on surrounding acoustical ceiling tile, offering a luminous and sound diffusive ceiling tile.
(9) The present invention shows how to utilize translucent microperforated or microslit facings, which do not require porous absorption behind them, to simultaneously diffuse light and provide sound absorption. The larger the air cavity between the microperforated or microslit panel and the light source, the lower the frequency of efficient absorption. A non-woven mat can optionally be placed behind the microperf or microslit facing to improve sound absorption and also minimize light leaks through the openings. In addition, a translucent and acoustically transparent non-woven veil may be added in front of the microperf or microslit absorber to match existing acoustical ceiling tile, which are faced with similar mats, creating a luminous ceiling tile. These non-woven mats are made from randomly dispersed glass fibers, wet or dry laid, and bonded into a thin sheet. The combined luminous absorber facing can be fabricated by creating a microperforated or microslit translucent plastic panel, by mechanical punching, drilling or laser technology.
(10) The combined fixture is designed to fit into typical T-bar sizes of 2′×2′, 2′×4′ or 4′×4′. The light diffusing fixture with either a sound diffusing or sound absorbing facade can be flush with the suspension grid or project below the grid plane into the room.
It is a first object of the present invention to provide a combination light diffuser and acoustical treatment and listening room including such fixtures.
It is a further object of the present invention to replace a traditional flat lighting diffusive facing with a translucent sound diffusing facing.
It is a yet further object of the present invention that a sound diffusing face can consist of random, geometrical, number theoretic or shape optimized topologies satisfying the desired scattering and diffusion coefficients as determined by ISO 17497-1 and 2, respectively.
It is a still further object of the present invention that the diffusive topology can be fabricated by thermoforming, injection molding, solvent welding, etc. with materials complying with UL and ETL standards for lighting fixtures.
It is a yet further object of the present invention to incorporate such a combined fixture in a typical T-bar ceiling grid.
It is a still further object of the present invention to design such a fixture so the diffusive element lies in the plane of the T-bar ceiling or below it.
It is a yet further object of the present invention that when the diffusive facing is in the plane of the ceiling, it is covered with a translucent and acoustically transparent non-woven glass mat with the same design as surrounding acoustical ceiling tile, providing a luminous and diffusive acoustical ceiling tile that blends in with the surrounding ceiling.
It is a still further object of the present invention to design the depth of the diffusive element to extend to a desired low frequency to control speech and music.
It is a further object of the present invention to replace the traditional flat light diffusing element with a translucent microperforated or microslit facing to provide sound absorption.
It is a still further object of the present invention to use multiple layers of microperforated foil to improve the sound absorption, as needed.
It is a yet further object of the present invention to design such a fixture so the absorptive element lies in the plane of the T-bar ceiling or below it.
It is a still further object of the present invention to design the cavity depth between microperf or microslit facing and the lighting source to appropriately absorb in a frequency range desired for speech or music.
It is a yet further object of the present invention to provide a deeper cavity, where it is desired to treat lower frequencies.
It is a still further object of the present invention that for increased absorption, multiple spaced layers of a microperforated foil can be used, with preferred spacing of 2 inches or greater, with a typical foil thickness of 0.1 mm, hole diameter of 0.2 mm, and hole spacing of 2 mm, having roughly as many as 30,000 holes per square foot.
It is a yet further object of the present invention that the microslit panel is preferably approximately 2-5 mm thick with slots approximately 0.2 mm wide and 10 mm apart, the slits being linear or custom designed providing similar open area. The absorption frequency response will depend on the panel thickness, the slot width and the slot spacing and is designed to provide useful absorption for speech and music.
It is a still further object of the present invention to digitally print graphic images on the translucent microperf or microslit sound absorbing facing offering illuminated images.
It is a yet further object of the present invention to place a translucent non-woven matt directly behind a microperf or microslit facing to minimize light streaking and maximize sound absorption.
It is a still further object of the present invention to cover a microperforated or microslit surface with a translucent and acoustically transparent non-woven glass mat with the same design as surrounding acoustical ceiling tile, providing a luminous and absorptive acoustical ceiling tile that blends in with the surrounding ceiling.
It is a still further object of the present invention to cover a perforated, microperforated or microslit foil or panel with a microperforated translucent, thin wood veneer and suitable backer, having up to 30,000 holes per square foot, providing a luminous and absorptive glowing wood light fixture to match and complement surrounding absorptive wood ceiling elements. An optional non-woven mat may be placed behind the perforated, microperforated or microslit absorptive element to increase absorption and uniformly disperse the light source.
It is a yet further object of the present invention that the preferred lighting source shall be low voltage LED to provide energy savings, minimize heat loading and operational cost, and remove AC from the ceiling plenum.
These and other objects, aspects and features of the present invention will be better understood from the following detailed description of the preferred embodiment when read in conjunction with the appended drawing figures.
a-c show how absorption removes the beneficial early reflections from the ceiling, reflection redirects them and diffusion uniformly distributes them for greater coverage and intelligibility.
a shows a front isometric image of a diffusive 2′×2′ lay-in fixture, which projects below the plane of the T-bar ceiling tile, illustrated in
b shows a rear isometric image of the diffusive 2′×2′ lay-in ceiling fixture of
c shows an image of a non-illuminated diffusive ceiling fixture in a 2′×2′ T-bar grid surrounded by conventional ceiling tile.
d shows an image of the diffusive ceiling fixture in a 2′×2′ T-bar grid of
e shows a front view of a 1D quadratic residue diffusive fixture with a non-woven mat fascia, as also depicted in
f shows a rear view of the diffusive fixture of
g shows a front view of the diffusive fixture of
h shows the fixture of
i shows a front view of an absorptive fixture with a non-woven mat fascia as illustrated in
j shows a rear view of the fixture of
k shows a front perspective view of the fixture of
a and 5b show exploded sections of typical 2′×2′ LED combined lighting and acoustical fixture.
As explained above with reference to
As seen, the walls are provided with absorptive upper portions that continue the absorptive periphery of the ceiling. The absorptive upper walls are designated by the reference numeral 21 while the absorptive ceiling periphery is designated by the reference numeral 23. The portions of the walls 13 and 15 below the absorptive portions 21 may be provided with diffusive surfaces to render uniform sound waves impinging upon them. Meanwhile, the front wall 25 is made of a reflective configuration as is the ceiling directly over a presenter standing at the podium 11 to more cleanly reflect his or her words toward the seats 9. The middle of the room 10 is provided with a ceiling configuration that is diffusive, designated by the reference numeral 27.
Of course, as is well known, the ceiling 17 typically includes a multiplicity of lighting fixtures to illuminate the room 10. The heart of the present invention is that of combining lighting fixtures with acoustical treatments. Thus,
b shows a second example of a lighting fixture 40 which is recessed with respect to the ceiling plane 41. The lighting fixture 40 includes illumination means consisting of a plurality of LEDs 43 and a sound diffuser 45 recessed above the plane 41 of the ceiling. A non-woven acoustical veil 47 is provided at about the plane 41 to shield the lighting fixture 40. The veil 47 can be made of a non-woven glass mat. The veil is acoustically transparent. The sound diffusers 35 and 45 are made of a translucent material so that light from the respective light sources 33 and 43 can penetrate the diffuser and be visible within the room where the fixture 30 or 40 is mounted. The spacers 46 support the light source 43 at an appropriate distance to provide uniform illumination.
With reference to
c shows top and side views of a convex diffuser 58 that has angled sides 59 and 60.
In
With reference to
With reference, now, to
With reference, first, to
With reference, now, to
i-L show views of a lighting fixture 160 that includes an absorptive fascia. The fixture 160 includes a frame 161 that is generally rectangular and the fascia is preferably a non-woven mat 163 that is seen to cover the entirety of the face of the fixture 160.
k shows a view of the fixture that should be compared to
The preferred embodiment of the combined light and sound diffuser consists of an LED lighting fixture, typically 2′×2′, with the conventional light diffuser replaced with a translucent sound diffusing surface, that satisfies the IES photometric data and the sound scattering and diffusion data as specified by ISO 17497-1 and ISO 17497-2. See
In the embodiments of
The preferred embodiment of the combined light and sound absorber (
While the light source in
In the embodiments of
Applicant has found that the deeper the sound diffusing element, the more optimal the low frequency response.
The teachings of the present invention are particularly advantageous in speech rooms and conference rooms to provide uniform illumination and sound coverage. In the preferred embodiments of rooms in accordance with the teachings of the present invention, the light fixtures combined with diffusers are located in the ceiling in a central area of the room to uniformly enhance communication and intelligibility between the speaker and the audience, the audience and speaker, and between respective audience members. The intent of the combined light/sound diffuser is to increase the signal to noise ratio of speech to thereby enhance speech intelligibility by providing early reflections which are fused by the auditory system in a louder and more intelligible signal. Sound absorbing elements are preferably employed around the perimeter of the room both in the ceiling and at the upper portions of the peripheral walls to control and limit reverberation.
The preferred embodiment for sound absorbing surfaces in accordance with the teachings of the present invention is based upon either microperforated or microslit technology. The sound absorbing quality and characteristics are preferably defined in accordance with ISO 354 or ISO 10534-2. To improve absorption, in the preferred embodiments of the present invention, a non-woven mat may be placed behind or in front of a microperforated or microslit element.
Decorative veils may be employed to match adjacent acoustical ceiling.
To increase sound absorption in the embodiments in which a sound absorber is incorporated into a lighting fixture, multiple layers of microperforated foil spaced apart by at least 2 inches in the vertical direction may be employed. The greater the cavity or spacing between the LEDs or other light sources and the acoustical treatments, the greater the low frequency response.
Hereinabove, the present invention has been disclosed in terms of certain kinds of room spaces to which it may be advantageously applicable. Applicant notes that the present invention including configurations of illumination means combined with acoustic treatments as well as other acoustic treatments in combination can be used in any room where music audition is important, including individual music rehearsal spaces, band rooms, choir rooms, distance learning rooms, recording in broadcast studios, rooms where plays and musicals are rehearsed and performed and any other possible room space. In such spaces, the dual functionality of the present invention, combining illumination with acoustical treatments simplifies design and aesthetics while also providing necessary acoustical control and modification.
Accordingly, an invention has been disclosed in terms of preferred embodiments that fulfill each and every one of the objects of the invention as set forth hereinabove, and provide new and useful combination light diffuser and acoustical treatment devices as well as listening rooms of great novelty and utility.
Of course, various changes, modifications and alterations in the teachings of the present invention may be contemplated by those skilled in the art without departing from the intended spirit and scope thereof.
As such, it is intended that the present invention only be limited by the terms of the appended claims.