The described embodiments relate generally to a ceiling system. More particularly, the present embodiments relate to a lighted ceiling system that provides a consistent appearance and lights a room, for example, a retail store.
Ceilings in rooms are often areas in which light sources are located.
Some embodiments of the present invention provide lighted ceiling panels and linear trough lights that emit an even light throughout their surface area, to evenly light the area above which they are installed. One or both of the lighted ceiling panels and linear trough lights can span an entire ceiling length to provide even light throughout an entire room.
Some embodiments of the present invention provide a number of panels disposed side-by-side in a ceiling area, spaced apart to form troughs therebetween. Together the panels and the troughs form a ceiling for a room. To maintain a consistent and aesthetically-pleasing look to the ceiling the panels may cover the majority of the ceiling, may each have the same width, and may be evenly spaced apart. The panels may present a clean visual appearance, and the troughs may provide a clear visual interruption between the panels.
Some embodiments of the present invention provide a ceiling system for a room, including a plurality of panels each having a length extending from one side of the room to an opposite side of the room. The panels may extend parallel to each other and may be spaced apart from each other to define a trough between adjacent panels. Each panel may include a panel frame and a continuous fabric cover tensioned over the frame and extending continuously along the length of the panel.
Some embodiments of the present invention provide an elongated light fixture including a frame having opposing vertically-arranged walls, a series of LEDs disposed on an interior side of each frame wall, a diffusing layer disposed between the frame walls, wherein the diffusing layer diffuses light from the LEDs, a backing layer disposed above the diffusing layer, wherein the backing layer reflects light from the LEDs, and a lens layer disposed below the diffusing layer, wherein light from the LEDs is emitted from the elongated light fixture through the lens layer.
Some embodiments of the present invention provide a ceiling system for a room including a plurality of longitudinal supports extending parallel to each other, wherein the longitudinal supports are disposed in a ceiling area of the room, a plurality of lighted panels extending parallel to each other and spaced apart from each other to define a trough between adjacent lighted panels, wherein each lighted panel is disposed between at least two of the longitudinal supports. Each lighted panel may include a panel frame coupled to the at least two longitudinal supports, a continuous fabric cover tensioned over the frame, and a lighting element disposed above the fabric cover. The ceiling system may also include a trough cover disposed within the trough, and a plurality of penetrations disposed within the trough and extending through openings in the trough cover.
Additional features of embodiments of the invention will be set forth in the description that follows, and in part will be apparent from the description, or may be learned by practice of the invention. Both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.
The disclosure will be readily understood by the following detailed description in conjunction with the accompanying drawings, wherein like reference numerals designate like structural elements, and in which:
Reference will now be made in detail to representative embodiments illustrated in the accompanying drawings. It should be understood that the following descriptions are not intended to limit the embodiments to one preferred embodiment. To the contrary, it is intended to cover alternatives, modifications, and equivalents as can be included within the spirit and scope of the described embodiments as defined by the appended claims.
References to embodiments, such as “an embodiment,” “some embodiments,” etc., indicate that the embodiment described may include a particular feature, structure, or characteristic, but every embodiment may not necessarily include the particular feature, structure, or characteristic. Moreover, such phrases are not necessarily referring to the same embodiment. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to affect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described.
The following examples are illustrative, but not limiting, of the present invention. Other suitable modifications and adaptations of the variety of conditions and parameters normally encountered in the field, and which would be apparent to those skilled in the art, are within the spirit and scope of the invention.
To illuminate a room, a light source may be attached to or integrated within a ceiling. In some cases, the light source may be a fixture hanging down from an area of the ceiling. In some cases, the light source may be positioned in a cut-out of a ceiling, or may take the place of a ceiling tile in a tiled ceiling. Such light sources may provide uneven lighting due to their discrete spaced-apart positioning with respect to the ceiling. For example, an area directly below a light source may be better-illuminated than one a distance away. Embodiments of the present invention provide lighted ceiling panels and linear trough lights that emit even light throughout their surface area, to evenly light the area above which they are installed. One or both of the lighted ceiling panels and linear trough lights can span an entire ceiling length to provide even light throughout an entire room. Such uniform lighting throughout a room provides consistent illumination of items within the room, regardless of their arrangement within the room. This can be ideal in a retail setting, where items and displays on the retail floor are subject to periodic change and reconfiguration. With uniform lighting throughout the room or an area thereof as provided by embodiments of the present invention, item and display configurations can be changed without regard to uneven lighting from discrete overhead light sources, since lighting throughout the area will uniformly illuminate throughout the area. In a retail environment this minimizes potential trade-offs between floor position and illumination level, and minimizes the potential need to reconfigure a room's lighting in order to optimize illumination of a new item or display configuration on the retail floor.
Lighting design for a room can be subject to a variety of requirements. For example, lighting must fit into the room structure (whether existing or newly fabricated), and may be designed so that its illumination conveys a desired character, meets regulatory requirements, and illuminates features of a room. Since rooms can be different, lighting systems may have to be custom-designed for a room to achieve consistent illumination across different rooms. Embodiments of the present invention provide a lighting system that is built upon a support structure that is adaptable to a wide variety of room shapes and configurations, while still providing consistent illumination.
Installations of the ceiling system of embodiments of the present invention may use one or more sub-systems as deemed necessary or expedient for the installation. The sub-systems may include, for example, (1) a panel sub-system that may include relatively wide lighted or non-lighted panels, (2) a trough sub-system that may include discrete lights within relatively narrow inverted troughs, and (3) a linear trough light sub-system that may include continuous light elements within relatively narrow inverted troughs. These sub-systems may be used separately or together in combination on the same support structure to suit the parameters of any installation. For example, the trough sub-system and/or linear trough light sub-system may be disposed between adjacent panels of the panel sub-system. In some embodiments the trough sub-system and linear trough light sub-system may include discrete utilities penetrating through the trough area to provide additional functionality to the ceiling system, such as, for example, cameras, additional lights, sprinklers, smoke detectors, and audio speakers. The wide configurability and functionality of the sub-systems of the ceiling system of embodiments of the present invention can be adapted to a wide variety of rooms and uses, while still providing a consistent look, illumination, and utilities between installations.
In some embodiments of the present invention, a room 20 may be illuminated by light sources of a ceiling system 10, which may be positioned in a ceiling area 26 of room 20. Ceiling system 10 may include panels 200 positioned parallel (or perpendicular) to each other and extending across a length of ceiling area 26. Ceiling system 10 may also define troughs 300 between adjacent panels. Exemplary configurations are shown in
In some embodiments, penetrations 400 may generate heat due to their operation. Penetrations 400 may be affixed to transverse struts 120 using a connector that acts as a heat sink, directing heat away from penetration 400 and dissipating it throughout support structure 100.
Different rooms 20 may have different characteristics. For example, structural support elements (e.g., ceiling subsurface or other structural supporting elements such as beams, joists, or purlins) of one room may be in different locations or may be more or less abundant than structural support elements in another room. Such structural support elements of a ceiling area 26 may be used to support ceiling system 10, so their positions, structure, and abundance may influence how ceiling system 10 can be supported.
In order to provide a consistent structural basis for panels 200 and troughs 300, a support structure 100 of ceiling system 10 may include transversely-spaced longitudinal supports 110 extending in a longitudinal direction L (see
Longitudinal supports 110 may be spaced to define a panel area 112 and a trough area 114, as shown, for example, in
To effect their relative widths, the distance between longitudinal supports 110 separated by a panel area 112 may be larger than the distance between longitudinal supports 110 separated by a trough area. For example, the distance between longitudinal supports 110 separated by a panel area may be 8 to 12 feet (e.g., 10 feet), and the distance between longitudinal supports 110 separated by a trough area may be 8 to 12 inches (e.g., 10 inches).
Panels 200 may occupy panel area 114, and troughs 300 may occupy trough area 114. Since panels 200 extend between longitudinal supports 110, the ability to freely position longitudinal supports 110 (as described above) helps to effect desired positioning of panels 200 and troughs 300, to achieve a desired appearance of ceiling system 10 and desired light characteristics from ceiling system 10.
Support structure 100 may include transverse struts 120 fixed to and extending between adjacent longitudinal supports 110. Transverse struts 120 may help maintain the relative positions of adjacent longitudinal supports 110 with respect to each other. Panel area transverse struts 122 may extend within panel areas 112, and trough area transverse struts 124 may extend within trough areas 114.
A number of panels 200 may be disposed side-by-side in ceiling area 26, spaced apart to form troughs 300 therebetween (see
Since panels 200 and elements of trough 300 are retained within ceiling area 26 by attachment to longitudinal supports 110, the ability to position longitudinal supports 110 as desired (described above) helps to effect the desired appearance of ceiling 28 by allowing panels 200 and troughs 300 to be arranged as desired. In some embodiments, to conform to a ceiling area 26 or to provide an angled look, ceiling 28 may be angled. In other words, one end of each panel 200 may be higher than its opposite end. Ceiling 28 can be angled longitudinally, transversely, or both. Angling ceiling 28 longitudinally may make room 20 appear larger or smaller, by influencing a viewer's perspective of the room in that direction. Angling ceiling 28 longitudinally may also help ceiling 28 to conform to an angled ceiling area 26, where, for example, a floor above ceiling area 26 is cantilevered over room 20.
In some embodiments, ceiling 28 may extend to walls 24 of room 20, to cover an entire ceiling area 26 of room 20 (see
The bottom surface of panels 200 may be defined by a cover material 250, which may be a flexible sheet material 252 such as plastic or fabric. Sheet material 252 may extend continuously (i.e., as a single continuous piece of fabric, without seams or other interruptions) over the entirety of a frame 210 of panel 200, to create a uniform, continuous look to ceiling 28. Since fabric (or other materials used for flexible sheet material 252) is flexible, its use to form the bottom surface of panel 200 contributes to the high configurability of panels 200. Frame 210 can be constructed to a desired size, and fabric 252 can be cut to size and applied to frame 210. This helps minimize the need to design and build specialized parts to install a consistent-looking ceiling system across a variety of different rooms.
In some embodiments, panel 200 (and thus continuous fabric 252) can be formed on a large scale. For example, having a width of at least 5 feet and a length of at least 32 feet. In some embodiments, a length of panel 200 is at least 500% of its width. For example, in some embodiments ceiling panels 200 are spaced apart 10 feet on center, with a 4 to 6 inch gap for trough 300, thereby resulting in a panel width of 9 feet, 8 inches. In other embodiments ceiling panel 200 may have a width of 7 feet. Generally, a wider ceiling panel 200 (e.g., greater than 8 feet) may be used for a lighted panel 202, while a narrower ceiling panel 200 (e.g., less than 8 feet) may be used for a non-lighted panel 204.
Also for example, in some embodiments, ceiling panel 200 and continuous fabric 252 have lengths of 40 feet, 50 feet, 60 feet, 70 feet, 80 feet, 90 feet, or 120 feet. Each trough 300 may have a length corresponding at least to the shortest panel 200 it is adjacent to. Troughs 300 may have a width substantially smaller than the width of panels 200. For example, each trough 300 may have a width less than 5% of the width of an adjacent panel 200. In some embodiments, each trough has a width less than 10% of the width of an adjacent panel 200.
In some embodiments, panels 200 may be mounted to longitudinal supports 110. Each panel 200 may include a frame 210 that provides structure to its perimeter, as shown, for example, in
Frame 210 may be rectangular, and may include short frame elements 214 extending transversely at ends of panel 200, and long frame elements 212 extending longitudinally along sides of panel 200. In some embodiments, frame 210 (and thus panel 200) may be non-rectangular in shape. For example, frame 210 may be trapezoidal or may be wedge-shaped (optionally with a curve at the front and rear ends). Also for example, frame 210 (and thus panel 200) may define a notch therein, to accommodate, for example, structural elements of room 20 such as the upper portion of a support column. Frames 210 (and thus panels 200) may be configured to fit around and into all portions of a ceiling area 26 to provide full coverage of ceiling area 26 so that ceiling 28 is defined consistently throughout by panels 200 and troughs 300.
In some embodiments, cover material 250 may be a fabric 252 that is tensioned across frame 210. Fabric 252 may wrap around bottom edges 218 of frame 210 and may engage with a tensioning mechanism of frame 210 that may accept and retain portions of fabric 252 so that fabric 252 covers the bottom area defined by frame 210. In this way, fabric 252 hides internal elements of panel 200 to present a consistent visual appearance.
Tensioning fabric 252 over frame 210 minimizes the possibility of wrinkles, bulges, or other non-visually-uniform configurations of fabric 252. In some embodiments, fabric 252 is placed into tension before being affixed to frame 210. In this case, a tensioning mechanism of frame 210 may help maintain the tensioned character of fabric 252. For example, the tensioning mechanism may include a mechanical fastener or adhesive that locks fabric 252 in position relative to frame 210.
In some embodiments, side covers 260 may be disposed over outer side 216 of frame 210, to hide frame 210 and to help present a consistent and continuous look for trough 300 (the sides of which may be defined by side covers 260 of adjacent spaced-apart panels 200). Side covers 260 may be affixed to frame 210 in any suitable manner, for example, by an attachment mechanism 224 such as a snap-fit, as shown in
In embodiments where panel 200 is a lighted panel 202, a light source 240 may be disposed above cover material 250. To produce a uniform light character throughout lighted panel 202, light source 240 may include LEDs longitudinally and transversely spaced apart throughout lighted panel 202. In some embodiments, light source 240 may emit light upward toward a backing disposed above light source 240. The backing may reflect and diffuse the light downward through cover material 250, to illuminate room 20 below. Reflecting and diffusing the light may promote a consistent light character through cover material 250, and may help minimize the appearance of bright spots due to the individual light elements (e.g., LEDs) of light source 240.
In some embodiments, fabric 252 may meet desired functional, aesthetic, and safety goals. For example, to achieve a consistent light quality through fabric 252, fabric 252 may have consistent characteristics throughout, including thickness, weave density, and color. Also for example, to fit securely to frame 210 in tension, fabric 252 may be elastic such that when it is stretched in tension, it tends toward its original shape. Such elasticity will help fabric 252 maintain an even and unwrinkled surface of panel 200. In the case of a woven fabric 252, fabric 252 may include elastic fibers to impart elasticity to fabric 252. In the case of a knitted fabric 252, elasticity may be imparted to fabric 252 by the form of knit used, by the incorporation of elastic fibers into fabric 252, or both.
Also for example, to achieve a consistent aesthetic look, fabric 252 may be free of visual defects and may have consistent coloring throughout. For example, fabric 252 may be white. White panels 200 may contrast with black troughs 300 to provide a clean, ordered aesthetic appearance to ceiling 28. White fabric 252 may also help to achieve the desired light characteristics through fabric 252 (e.g., soft, natural light). To achieve desired safety characteristics, fabric 252 may be fireproof, in that it will not burn if subjected to flame (e.g., class A international fire-rated).
To achieve these and other goals, fabric 252 may be an industrial glass fiber fabric such as glass cloth. Glass fiber is not combustible.
As noted above, fabric 252 may be formed in large sizes (e.g., 32 feet, 40 feet, 50 feet, 60 feet, 70 feet, 80 feet, or 90 feet). To achieve such large sizes while maintaining the desired functional, aesthetic, and safety qualities of fabric 252, fabric 252 may be formed continuously over the desired length and width, without seams or interruptions.
Troughs 300 separate adjacent panels 200, and thus extend the same lengths as the panels 200 they are adjacent to (or at least the length of the shorter of two adjacent panels 200, in the event that adjacent panels 200 have different lengths). Elements of troughs 300 are supported by longitudinal supports 110 and trough area transverse struts 124 that extend therebetween (see, e.g.,
Trough area transverse struts 124 may support trough elements such as, for example, penetrations 400. Positioning penetrations 400 within trough area 114 helps minimize their visual impact within ceiling system 10, while maintaining their functionality.
In some embodiments, T-bars 310 are disposed within trough area 114. Each T-bar 310 may be coupled to a trough area transverse strut 124, as shown in
Central cover 320, upper covers 330, and side covers 260 (of panels 200, discussed above) define trough 300 and help maintain a consistent look of trough 300 by hiding internal structure of ceiling system 10. For consistency in appearance, all covers 320, 330, and 260 may be the same color (e.g., black), and may have a flat, unornamented surface facing the inner area of trough 300. To achieve the same color covers 320, 330, and 260 may be painted or anodized.
Central cover 320 is attached to and extends between T-bars 310 via attachment mechanisms 312.
The arrangement of T-bars 310, central cover 320, and upper covers 330 allow for airflow through trough 300 without providing a visually-apparent airway or duct. As shown in
Upper covers 330 are attached to and extend between T-bars 310 via attachment mechanisms 332. In some embodiments, attachment mechanisms 332 include a hinged detent fit between top flange 314 of T-bar 310 and upper cover 330. The hinged detent fit, when engaged, may maintain upper cover 330 in a horizontal position to hide elements above it from view. When the hinged detent fit is disengaged, upper cover 330 may rotate about a longitudinal axis while still being retained within trough 300 (see
Troughs 300 at peripheral sides of ceiling 28 may be adjacent only one panel 200. In this case, on the side opposite panel 200 there may simply be an empty space, or a wall 24 of room 20, as shown in
To effectively provide their respective functionalities, penetrations 400 may extend through openings 322 in central cover 310.
Penetrations 400 may extend beyond central cover 320 by any desired distance. For example, downlight 410 may extend to a bottom surface of panels 200, in order to present a consistent visual impression and, in the case of lighted panels 202, a consistent plane of light sources. Some penetrations 400 may not extend as far as the bottom surface of panels 200, and some may extend beyond the bottom surface of panels 200. For example, to minimize its visual impact, smoke detector 440 may not extend to the bottom surface of panels 200, since it can effectively perform its function while remaining recessed therefrom. Also for example, camera 420 and sprinkler 430 may extend below the bottom surface of panels 200, so that panels 200 do not interfere with their functions (see, e.g.,
To maintain visual consistency with other elements within trough 300, penetrations 400 may be disposed within a penetration sleeve 402. Penetration sleeve 402 may protect and hide the internal structure of its penetration 400. Penetration sleeve 402 may extend through central cover 320 at an opening 322 thereof. Opening 322 may be fitted with a fixing ring 404 and escutcheon 406 to provide a clean passageway for penetration sleeve 402 and to hide edges of central cover 320 around opening 322.
A bottom edge or surface of penetration sleeve 402 may extend to and align with the bottom surface of panels 200, in order to present a consistent visual impression. In some embodiments, penetration sleeve 402 may be colored the same color as central cover 310 (e.g., black), so that visually the sides of penetrations 400 blend in with central cover 310 to minimize their visual impression within trough 300. In some embodiments, central cover 310, upper covers 320, side covers 260, and penetration sleeves 402 are the same color (e.g., black), so that trough 300 presents a consistent visual impression throughout its length, with minimal obvious visual interruption or distraction.
In some embodiments, audio equipment may be incorporated into ceiling system 10, to provide audio signals (e.g., alarms, music, or voice) while hiding the audio equipment from view and while maintaining high sound quality. To avoid interference with sound by panels 200 (e.g., muffling of sound waves as they pass through panels 200), and to avoid interfering with light produced by panels 200, speakers 710 of a trough audio system 700 may be positioned within trough area 114 (e.g., directly in trough 300, see
In some embodiments, speakers 710 are retained above openings 322 in central cover 320 by a speaker bracket 712. In some embodiments speakers 710 are securely anchored to trough area transverse struts 124. In some embodiments, speakers 710 avoid direct contact with other elements (such as central cover 320) in to avoid sound degradation (e.g., buzz due to vibrations from contacting other elements) and provide optimum sound output from trough 300 to room 20.
To further achieve high sound quality, in some embodiments sound system 700 may include a subwoofer 720, which may also be disposed within trough area 114 (see
In some embodiments, rather than having a cover plate in trough 300, trough 300 includes a linear trough light 500, as shown, for example, in FIGS. 2 and 23-39. As shown in
In some embodiments, frame 510 forms an inverted “U” shape having a horizontal upper section 512 and two vertical sides 514. Vertical sides 514 may include inwardly-extending flanges 512 along their edges.
A light source 520 may be disposed on the inner sides of one or both of sides 514. In some embodiments, light source 520 includes a plurality of LEDs, which may take the form of a strip of side-firing LEDs 522 as shown in
Frame 510 may be coupled to trough area transverse struts 124 to thereby retain frame 510 within trough 300. Frame 510 may interconnect with other elements of linear trough light 500 to retain them within trough 300 as well (see
One or more diffusing layers 540 may be positioned in alignment with LEDs 522, such that light emitted by LEDs 522 is received by diffusing layer 540. Diffusing layer 540 may be formed of one or more layers of a clear acrylic having a pattern 542 applied thereon or formed therein that diffuses the light received and directs it downward toward lens 550. Some light may also be directed upward toward backing layer 530, which may have a reflective surface to as to reflect incident light downward toward lens 550, where it is output to room 20. To help reflect light, and to help provide a consistent look throughout linear trough light 500, backing layer 530 may be white. In some embodiments backing layer 530 may be a single layer, as shown in
To evenly draw in and diffuse light from LEDs 522, diffusing layers 540 (e.g., first diffusing layer 540a and second diffusing layer 540b) may be spaced apart from each other, as shown, for example, in
To avoid interfering with light passing therethrough, lens 550 may be formed of a clear material, for example, acrylic, for example, heat polished acrylic, for example, Polymethyl methacrylate (PMMA).
A pattern 542 may be formed on or in one or more layers of diffusing layer 540 by etching (e.g., laser etching), or may be stamped upon one or more layers of diffusing layer 540 by a mold (e.g., a metal mold with pressure and heat applied). To promote uniform light diffusion throughout diffusing layer 540, pattern 542 may become more dense (i.e., spacing between pattern features may decrease) as its distance from LEDs 522 increases. For example, in an embodiment with LEDs 522 along both sides of frame 510, pattern 542 may be formed of spaced-apart longitudinal lines etched or otherwise applied to diffusing layer 540. The space between adjacent lines may decrease (i.e., the pattern may become more dense) as they approach the center of diffusing layer 540.
Penetrations 400 may extend through linear light trough 500 in a similar manner as they may extend through central cover 320, described above.
As shown, penetration sleeve 402 may surround penetration 400 (e.g., downlight 410, camera 420, and sprinkler 430) to protect and hide its internal structure, as described above. Some penetrations 400 (e.g., downlight 410 and camera 420) may be coupled to and supported by their penetration sleeves 402. Others (e.g., sprinkler 430) may extend through their penetration sleeves 402 without contacting their penetration sleeves 402. For some penetrations 400 (e.g., smoke detector 440), no penetration sleeve is used. In the case of smoke detector 440, no penetration sleeve is needed since smoke detector 440 can detect smoke from above linear trough light 500 through a smoke detector opening 442 through linear trough light 500.
Penetration sleeve 402, and penetration 400 contained therein, may extend through an opening 518 in upper section 512 of frame 510, and may further extend through corresponding openings in backing layer 520, diffusing layer 540, and lens 550 of linear trough light 500. A bottom edge or surface of penetration sleeve 402 may extend to and align with the bottom surface of lens 550, in order to present a consistent visual impression.
Providing penetrations 400 within trough 300 allows them to perform their functions without interfering with the visual impression of panels 200. Their alignment and consistent structure and appearance (e.g., from penetration sleeves 402) within trough 300 provides an ordered and consistent appearance between panels 200.
A plurality of linear trough light segments 500 may be arranged end-to-end within trough 300. Breaks 570 between adjacent linear trough light segments 500 may create a visual interruption (see
In some embodiments, to minimize the visual impact of trough 300, bottom edges 218 of frame 210 may be angled outward, into trough area 300, as shown in
As shown in
Avoiding interference with light cone 620 and other elements of ceiling system 10 can help to avoid creating distracting shadows and hard edges to the light provided by recessed light 610. A light fixture such as recessed light 610 may be preferable to downlight 410 in some ceiling system 10 installations. For example, recessed light 610 may better illuminate a room 20 having a lower ceiling, while downlight 410 may better illuminate a room 20 having a higher ceiling.
As described above, panels 200 may be large, having continuous elements such as fabric 252 extending their length and width. To install such a large panel 200 in a ceiling area 26 of a room 20, support structure 100 may include hoisting mechanisms that may be used to hoist panels 200. The hoisting mechanisms may be mounted to longitudinal supports 110 so as not to be visible from below. Hoisting cables may extend from hoisting mechanisms to connect to a panel 200 to be hoisted.
Panel 200 may be constructed before installation within ceiling 28. For example, fabric 252 may be laid out on a floor and frame 210 of panel 200 may be constructed on the floor (e.g., on fabric 252) below its intended location in ceiling 28. After frame 252 is constructed, fabric 252 may be tensioned over frame 210 and attached thereto. A light source 240 may also be incorporated into panels 200 during construction. Hoisting cables may be fixed to frame 210 of panel 200. Once panel 200 is constructed and hoisting cables are secured to frame 210, panel 200 is ready to be hoisted into place.
For large-scale panels 200, construction outside the ceiling area 26 (e.g., on the floor below) simplifies construction as opposed to in-ceiling construction, since workers do not have to worry about suspending the elements of panel 200 while constructing it.
The foregoing description, for purposes of explanation, used specific nomenclature to provide a thorough understanding of the described embodiments. However, it will be apparent to one skilled in the art that the specific details are not required in order to practice the described embodiments. Thus, the foregoing descriptions of the specific embodiments described herein are presented for purposes of illustration and description. They are not exhaustive and do not limit the embodiments to the precise forms disclosed. It will be apparent to one of ordinary skill in the art that many modifications and variations are possible in view of the above teachings.
For example, although the ceiling system of the present invention has been described with reference to a ceiling, its principles apply to other building features structures such as walls, floors, and roofs.
The elements of the embodiments presented above are not necessarily mutually exclusive, but may be interchanged to meet various needs as would be appreciated by one of skill in the art. The breadth and scope of the present invention should not be limited by any of the above-described exemplary embodiments, but should be defined only in accordance with the following claims and their equivalents.
Number | Name | Date | Kind |
---|---|---|---|
3030670 | Bigelow | Apr 1962 | A |
4625267 | Mikalonis | Nov 1986 | A |
5282331 | Fell | Feb 1994 | A |
5620369 | Spransy et al. | Apr 1997 | A |
6351920 | Hopkins et al. | Mar 2002 | B1 |
6467209 | Vickers | Oct 2002 | B1 |
20110175533 | Holman et al. | Jul 2011 | A1 |
20130070455 | Tsui et al. | Mar 2013 | A1 |
20130301249 | Ngai et al. | Nov 2013 | A1 |
20140168954 | Gershaw | Jun 2014 | A1 |
20140313774 | Myers et al. | Oct 2014 | A1 |
20140313775 | Myers et al. | Oct 2014 | A1 |
20140313780 | Myers | Oct 2014 | A1 |
Number | Date | Country |
---|---|---|
1 375 771 | Jan 2004 | EP |
WO 2005073482 | Aug 2005 | WO |
Entry |
---|
Communication Relating to the Results of the Partial International Search. International Application No. PCT/US2015/014636, European Patent Office, mailed on May 19, 2015. |
Number | Date | Country | |
---|---|---|---|
20150225948 A1 | Aug 2015 | US |