The present invention relates to a combination lighting and audio communication system for use in ceilings and walls, and more particularly to a modular system for providing both light and sound in a commercial suspended ceiling panel system.
It is well known in the art to use various types of incandescent and fluorescent light sources for residential and commercial buildings, mounting them into a ceiling tile or drywall type ceiling or wall. Light sources are provided in either surface mounted or recessed configurations, and in the case of recessed mountings the housings can be cylindrical, square or rectangular. The square and rectangular light sources can be sized for mounted directly into ceiling grids where no cutting of tiles is required.
There have been recent developments which utilize low voltage or Light Emitting Diode (LED) sources in place of the traditional incandescent and fluorescent lights. These LED arrays are smaller in physical size with a nearly flat profile, lending themselves to low ceilings with limited plenum space or even low profile surface applications. The LED arrays are also much more energy efficient that traditional light sources, and offer the option of multiple colors and rapid on/off cycles.
It is also well known in the art that various speaker arrangements are used in a variety of recessed enclosures intended for use in suspended and drywall type ceilings and walls in residential and commercial buildings. The speakers can be either the traditional cone and magnet type, or a transducer type attached to a transmitting surface. Other audio sources can also be incorporated, such as sirens, piezo buzzers, whistles and the like. Traditional speakers can be furnished in specialized audio ranges such as woofers, mid-range, and tweeters. The various audio devices can be powered by a centralized amplifier, and controlled by an audio source such as a radio, CD or MP3 player, microphone, or computer controlled announcement system. The audio source can send a single output signal such as background music or paging to all the speakers, or it can send specialized audio outputs to speakers in certain zones, such as localized announcements in airports. The audio devices can also be supplied with a receiver to receive wireless transmission of an audio signal from a remote transmitter.
Ceiling and wall mounted lights and speakers are generally mounted separately from each other, as the electrical power and control systems for each are completely different. There have been some light and speaker combinations proposed for recessed mounting in ceilings and walls, but most of these known systems are intended for home use, and were not envisioned for large commercial applications. In addition, the lighting in these configurations was intended strictly for illumination, and did not have any implications for emergency assistance such as fire, weather emergency, or other communication applications. Combination lights and speakers have consisted of lights mounted directly in front of the speaker components, which has wattage limitations in terms of heat generation, and can create a fire hazard if the lamps used become too hot.
The present invention includes lighting and audio components in the same fixture to create a lighting and communications panel. The panel assembly includes a square or rectangular enclosure having a size and shape often corresponding to various suspended ceiling tiles or modular lighting. The edges of the enclosure are configured to fit into standard ceiling grids, or to be flush mounted into a new or existing wall or ceiling structure. There is a lighting element generally parallel with the front edge of the tray, and which covers substantially the entire opening of the tray. The lighting element can consist of traditional lighting sources such as incandescent, fluorescent, neon, or HID.
Alternatively the lighting element used in the assembly may consist of an LED array, of generally two types. A top firing LED array has many LED's positioned in grid patterns on a generally flat panel. This plurality of LED's can be programmed to light individually in a desired sequence, in order to form letters, numbers, or various shapes including arrows, chevrons, logos, or symbols. The shapes and symbols can be programmed to scroll along a linear path, or to simulate motion in any direction.
A second variation is a side firing LED array, in which LED's are arranged around the edge of a translucent panel, to light the panel from only the edges. In either configuration, the LED's are capable of changing color, so the desired shapes can also be programmed in many color combinations. The side firing LED array also lends itself well to a transducer type audio system, which would keep the overall height of the assembly very low. Either of the lighting arrangements can be controlled from a common power source and switched in banks similar to traditional lighting schemes. Alternatively, the lighting assemblies can be individually controlled from a computer or circuit board driven system which would allow individual control of each light assembly and facilitate communication via changing colors or shapes generated by the lights.
The lighting tray assembly also includes at least one audio speaker driver which is mounted on top or in back of the tray so that it is not visible after mounting of the assembly. Normally this audio system will be in a completely different compartment than the lighting, separating the two systems for better heat and vibration resistance, and compliance with commercial fire codes. In order to route the audio waves from the rear of the tray to the front of the assembly, at least one flat horn is utilized. This flat horn, in one configuration accepts the sound from the audio speaker driver, extends laterally around the back of the tray, and exits out at least one narrow slot at the front of the assembly. In another configuration, at least one speaker driver is used in combination with at least two flat horns, to direct the sound along at least two separate paths to two narrow outlets in the front of the enclosure. In this way, the speaker is concealed, virtually the entire surface of the lighting array is maintained, and the audio waves can travel unobstructed from the driver to the narrow front outlets. The shape of the flat horns can be adjusted to create the audio signal desired. For example the horns can have the same cross section from their audio source to their outlet, or they can expand in size from the source to the outlet, or even reduce in size as they approach the outlet. The horns can even be created in a labyrinth so that a long horn path can be contained in a smaller space. These light and speaker assemblies can be arranged throughout the ceiling area, in order to deliver distributed light and sound throughout the area.
Another configuration is to utilize a transducer type audio system where one or more audio transducers are attached to a flat panel to transmit the audio signal directly without the use of the flat horn to direct the sound waves.
While the speaker system can certainly be used for the more traditional background music, white noise or paging functions, the combination with the versatile LED lighting array creates some very unique opportunities. For example, the lights can be individually and independently programmed to respond in pre-determined ways to certain audio signals. For example, in the case of a fire signal sent to the audio system, the lighting system can display red arrows or chevrons indicating the best path to an exit. The LED array could also display scrolling text to indicate the emergency or hazard, including several languages or pictorial displays. Weather, chemical, or other hazard situations could be handled in a similar fashion. A code blue emergency in a hospital setting could be programmed to indicate blue chevrons to guide responders to the appropriate location while the audio system announces the information.
An additional opportunity would be for the lights to respond automatically to a particular audio frequency. For example, the LED's can be programmed to display chevrons or text in response to a known fire alarm or siren frequency. This programmed response could be passive, meaning that it would work with remote audio sources not directly connected to the communications panel itself.
In addition to ceiling grid and wall mounted applications of this invention, there are also many other opportunities which the inventors have envisioned, including;
The above and other objects and advantages of the present invention will become more apparent from the following description taken in conjunction with the following drawings in which:
A speaker housing 38 provides a protective covering over the speaker 34, and is often required by local or federal fire codes. The speaker housing 38 is a generally pan or bowl shaped assembly with one open side defined by a speaker housing flange 40 around the perimeter. The speaker housing 38 can be designed in a variety of shapes and sizes depending on the particular application, and is generally attached via the speaker housing flange 40 to the horn enclosure back 22 using clips, adhesive, hinges or fasteners (not shown).
The speaker housing 38 can also be used to mount and protect various other equipment 42, which may include wiring, amplifiers, transformers, or wireless receivers. The speaker housing 38 can also provide an enclosure for a lighting circuit board 44 for controlling various lighting functions or other aspects of the device.
As shown in
The space created between the light enclosure back 74 and light enclosure side 76 of the light enclosure 70, and the horn enclosure back 22 and horn enclosure side 26 of the horn enclosure 20 defines a horn expansion area 86. The purpose of the horn expansion area 86 is to guide sound waves 88 emanating from the speaker 34 towards the audio aperture 60 of the trim ring 50 and into the ambient area adjacent the horn enclosure opening 30. In order to further guide the sound waves 88, a bifurcation bar 90 may be attached to either the light enclosure back 74 or the horn enclosure 20 to split the sound waves 88 into two or more directions of flow.
Inside the light cavity 78 is a light source 82 which is electrically powered with either a 120 VAC house current or a low voltage power supply, and attached to the light enclosure back 74. One embodiment of the light source 82 is an LED array 84, which consists of a plurality of bulbs in a plurality of rows. Other light sources 82 include fluorescent or incandescent lights. There may be a plurality of tabs 72 at various heights along the horn enclosure sides 26 to allow a number of different distances between the light enclosure 70 and the lens 58 to provide a variation of diffusion levels of the light source 82.
The light sources 82 or LED array 84 may be controlled by a lighting circuit board 44, which can also be located remotely to control a series of lights. The lighting circuit board 44 can control many aspects of the LED array 84 including brightness, color, patterns, text, scrolling, graphic movement, and power management.
The light source 82a in this application consists of a side firing LED array 84a where the LED's are disposed around one or more edges of the lens 58a of the light enclosure 70a. A relatively flat speaker housing 38a is disposed above the light enclosure 70a to protect the transducer 100a of the speaker 34a, and is removably attached to the frame 50a of the light enclosure 70a. The result of this configuration is a more flat overall shape, capable of being mounted in a ceiling grid, but more appropriate for surface or wall mounting.
This application claims the benefit of provisional application Ser. No. 61/211,664 filed Apr. 2, 2009 naming the same inventors.
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