WO1980002735A1

WO1980002735A1 - Luminaire for indirect lighting

Info

Publication number: WO1980002735A1
Application number: PCT/US1980/000708
Authority: WO
Inventors: P Ngai; D Herst
Original assignee: P Ngai; D Herst
Priority date: 1979-06-08
Filing date: 1980-06-06
Publication date: 1980-12-11

Abstract

The luminaire includes a source of light (L1, L2) in an opaque housing (15) which extends beneath the source and upwardly about the sides of the source to hide the source from direct view from a horizontal line of sight even with the source. A lens (41) is mounted to the housing above the source and extending around to join with the upper edge of the housing. The lens includes an upper light-dispersing portion (48) which diverges one portion and only displaces another portion of the light from the source to provide an even distribution of luminance to a ceiling above the source. The lens also includes a lateral light-bending portion (50) which receives light from the source and fans it out laterally over the side of the housing to continue the uniform illumination pattern of the ceiling and to illuminate vertical surfaces in the vicinity of the luminaire. A reflector (30) beneath the source directs light onto the lateral light-bending portion of the lens to at least partly compensate for the fact that the light passing through the lateral portion of the lens normally travels farther to the surface it is illuminating and also strikes horizontal surface at an increased angle of incidence. The lens and housing cooperate to enclose the source of light to prevent dust from entering, and the lateral portion of the lens provides a visible source of light to a person in the room being illuminated.

Description

LUMINAIRE FOR INDIRECT LIGHTING Background and Summary

The present invention relates to a luminaire (i.e., the complete lighting unit); and more particularly, it relates to a luminaire which may be used for indirect lighting particularly in large open areas such as are commonplace in modern offices. As will be further explained below, one of the advantages of the invention is that its use is not limited only to open office areas, but rather, it can be carried through to the lighting of hallways, executive suites or conference rooms. However, the invention is particularly suited to provide illumination for typical office situations with efficient use of energy while having those characteristics which recent research has shown to be desirable from a psychological viewpoint.

Modern offices are characterized by large open spaces having a ceiling height normally about eight feet, but which may extend to nine feet. The space may be sectioned for privacy by movable wall partitions. These partitions normally have a height of about five to seven feet.

In considering the lighting requirements for an office, among the more important considerations are the need for individual task lighting, for example, for surfaces approximately two and a half feet above the floor, and the need to provide some ambient lighting. The latter is desirable both from a safety standpoint and for psychological reasons, as will be discussed below.

Direct lighting as a source of lighting for offices provides high luminance for task areas, but in general, the quality of lighting is not good in terms of visibility and visual comfort of a person.

Lenses have been used in luminaires employing fluorescent lamps for direct lighting. One type of lens employs individual conical or sperical lenses in a repeating pattern. Another uses parabolic reflectors to direct light downwardly. In both of these systems, a light transmission pattern is created in which the light is directed downwardly and generally confined within an angle of about 45 degrees from the vertical. Further, neither of these systems provides ambient lighting for vertical surfaces which has been found to be a distinct preference and produces feelings of spaciousness and comfort.

Indirect lighting obviates the problem of glare perceived by an observer, but most indirect lighting systems have the disadvantge of collecting dust which gathers on the lamps and any reflectors beneath the lamps, arid this is a major source of reduced luminance. Another disadvantge of most indirect lighting systems is a psychological one. Research has shown that human beings have a distinct preference for lighter rooms which are uniformaly illuminated. In other words, a person may comfortably perform a task in an area at a relatively low luminance level provided there is a minimum of light available and the luminance pattern does not change substantially within his field of view. If the luminance level is substantially lower than that of the area from which a person enters, there will be a period of adaptation, but-once the adjustment has been effected, there is little difficulty in performing tasks if the illumination meets the minimum requirements for the task. Further, people prefer to be able to see the source of light. It provides a sense of perspective and has been found to be a factor to be considered in providing office lighting. As indicated, most indirect lighting systems have a principal object the generation of light while masking completely the origin of the light.

Lenses have in the past been placed above a source of light. Some of these lenses do not generate a pattern of illuminance above the luminaire which is uniform. Either a very bright spot is created above the luminance (the more common characteristic), or a dark area is generated. In either case, the substantial variation in the illumination pattern on the ceiling is easily perceived and is undesirable. Further, in the case of the bright spot, inefficiency results because most of the light is reflected back to the luminaire rather than being used to light the room.

If a dark area is created on the ceiling, it is undesirable from an aesthetic as well as a psychological viewpoint because of the preferences mentioned above. The luminaire of the present invention has as a principal object the provision of indirect lighting of large open office systems by achieving a uniform distribution of light (i.e. illumination pattern) on a ceiling over the luminaire as well as by fanning the light out laterally to extend the uniform luminance on the ceiling to adjacent areas not directly above the luminaire. Further, due to the reinforcement and bending of lateral rays, vertical surfaces are illuminated even at a substantial distance from the unit.

The luminaire includes an opaque housing beneath the source of light which preferably includes two or three fluorescent lamps placed side by side. The length of the lamps helps to distribute the light along the length of the housing.

A lens is mounted to the housing above the source, and in the illustrated embodiment, it includes a generally flat upper portion and lateral portions which curve downwardly and join to the housing to enclose the lamps. The upper portion of the lens includes a flat upper surface and a series of light-diverging prisms on the lower surface, facing the source of light. Adjacent prisms are spaced by a flat portion. The function of the prisms is to refract and diverge incident light, and the function of the flats is to permit incident light to pass between the prisms. The prisms and flats cooperate to provide a uniform pattern of luminance on a ceiling above the luminaire which normally has a high reflectance to provide good indirect lighting qualities. This uniformity is effective when the ceiling is placed about two to three feet above the upper surface of the lens and the effect persists even though the spacing is reduced to one foot.

A reflector is located beneath the light sources in the housing to direct light from the sources out to the lateral portions of the lens. Some of the reflected light is transmitted upwardly to the upper portion of the lens. In the illustrated embodiment there are two lateral lens portions, but only one is necessary, for example, if the luminaire is designed for placement directly on the side of a vertical wall. The lateral lens portion or portions are curved downwardly from the top lens portion to the upper edge of the housing, and they contain a plurality of external prisms extending the length of the lens The placement of the source of light in the housing is such that it cannot be seen directly by an observer having an eye level the same height as or slightly above the source. Further, because of the interposition of the lens, the light source cannot be seen directly from any elevation. The lateral lens portions bend the light from the source as well as the light from the reflectors toward the horizontal to "fan" the incident light and thereby extend the uniform pattern of luminance onto portions of the ceiling not directly above the luminaire. A pattern of luminance having substantial uniformity is thus achieved on the ceiling directly overhead and extending a few feet either side of the lens without creating bright spots which cause glare or dark areas on the ceiling, as characterized by some prior luminaires used for indirect lighting. Thus, luminaires of the present invention may be spaced at relatively wide distances-if they are associated, for example, with movable wall panels since adjacent luminaires will both exhibit this fanning effect and achieve a luminance for indirect lighting which not only provides uniform ambient lighting but also more than adequate task lighting at the same time.

The fact that the light flux density diminishes as the distance between the luminaire and the point being illuminated increases as well as the fact that the flux density is reduced because the flux density in a plane perpendicular to the source is spread over an extended area for large angles of incidence (i.e. the angle relative to the normal), as is the case for are not directly above the luminaire, are compensated by the effect of the reflector which routes most of the light from the bottom of the source toward the lateral lens portions, although some is transmitted to the top lens portion because of the size of the lamps. This, as well as the particular prism designs, disclosed below, cooperates to achieve a pattern of substantially uniform luminance which is highly desirable from a psychological standpoint and which achieves uniform task light as well as ambient lighting while reducing the amount of electricity to accomplish this in a large open office area. The lateral lens portions of the luminaire transmit direct and reflected light from the source to illuminate vertical surfaces such as walls and provide a brighter ambient lighting.

Further, because the prisms on the curved lateral portion of the lens are on the exterior surface of the lens, they act to segment the incident light and provide a series of softly glowing lines of light which are perceptible to a person standing to the side of the luminaire, but without transmitting a direct image of the source. Thus, persons in a space illuminated by the present invention have the psychological benefit of knowing where the light is coming from, yet they do not experience the discomfort of glare which accompanies normal direct lighting. When the luminaire of the present invention is mounted to the top of a movable wall panel at a height of 72 to 84 inches, the light source is out of the direct line of sight of a person less than about seven feet tall. Nevirtheless, he is capable of seeing light emanating from the exit surfaces of the prisms on the curved lateral portions of the lens. A small amount of light also emanates from the riser surfaces of the prisms through internal reflection, and this light is greatly diminished in luminance, but it extends downwardly from the luminaire, thereby providing a visual image of the source of light even to a person sitting at a work surface mounted to the same or adjacent wall panel to which the luminaire is mounted.

Another advantage to the present invention is that the lens provides a dust cover for the lamps, and the smooth exterior surface of the upper portion of the lens facilitates cleaning. That is, there are no crevices in which dust can gather. Thus, a major source of reduction of luminance in indirect lighting is obviated, namely, the collection of dust on the lens or lamps.

Other features and advantages of the invention will be apparent to persons skilled in the art from the following detailed description of a preferred embodiment accompanied by the attached drawing wherein identical reference numerals will refer to like parts in the various views. The Drawing

FIG. 1 is a side elevational view of a typical movable panel wall system on which a luminaire constructed according to the present invention is mounted;

FIG. 2 is an upper side perspective view of the luminaire Of FIG. 1;

FIG. 3 is a transverse cross sectional view of the luminaire of FIG. 2;

FIG. 4 is a fragmentary longitudinal vertical cross sectional view of one end of the luminaire of FIG. 2; and

FIG. 5 is a diagrammatic cross sectional view of the right side of a lens incorporated into the luminaire of FIG. 2.

Detailed Description

Referring first to FIG. 1, reference numeral 10 generally designates a movable wall panel at the top of which a luminaire generally designated 11 is mounted by means of an upright mount 12 extending from the top of the panel 10. The mount 12 may take the form of a pair of upright arms enclosed in a sheet metal casing.

To illustrate the type of task lighting to which the present invention is directed, a cabinet generally designated 13 may be mounted to the wall panel 10, and a work surface 14 may be provided beneath the cabinet 13.

Turning now to FIG. 2, the fixture 10 is seen to include a housing 15, first and second end caps 17, 18 and an upper lens 19.

As best seen in FIG. 3, the housing 15 includes a generally flat bottom wall 21 and upwardly curved side walls 22, 23. The housing 15 may be formed by extruded aluminum since its cross section is uniform throughout. It is then cut to the desired length.

On the side wall portion 22, there is formed a screw mount 25, and a similar screw mount 26 is formed on the inner surface the side wall 23. First and second inwardly extending lips 27, are formed at the upper edges of the side walls 22, 23 respectively. A reflector generally designated 30 is mounted in the housing 15 by screws 31 secured in the screw mounts 25, 26. The reflector 30 is symmetrical about a vertical plane P extending through the longitudinal center of the luminaire to form side halves 33, 34. Thus, the side 33 includes a flat portion 35 beneath a first lamp L1; and to the side of the lamp L1, the reflector is smoothly curved upwardly to form a portion 36, the edge of which is formed into a mounting flange 37. The central portion of the reflector is turned upwardly as at 39. The surface of the reflector may vary according to the effect desired, but for general office use, a specular surface may be used.

The illustrated embodiment includes a second lamp L2 located within the housing 22. Both lamps are mounted between a pair of conventional lamp holders, one of which is shown in FIG. 3 at 39 mounted to a first intermediate wall 30. A third lamp may be used by~moving the two lamps shown further apart and inserting a third lamp between them. The center lamp would be raised slightly. The luminaire may also be used with only a single lamp or with a switch for illuminating one, two or three lamps, as desired.

A lens generally designated 41 is mounted to the housing 15 by means of first and second elongated fittings 44, 45 which releasably couple respectively to the inwardly extending lips 27, 28 of the housing 15. Thus, the lens is mounted in such a manner that it can be removed easily, simply by pressing the sides, yet it prevents dust and dirt from entering the interior of the luminaire. The end seals will be described in connection with FIG. 4.

The lens 41 includes an upper lens portion 48, and first and second curved lateral portions 49, 50. The lens 41 is also symmetrical about the plane P. Because both side halves of the fixture operate in a similar manner, the features and advantages of the invention can be achieved simply by extending the housing along the plane P for a luminaire adapted to mount to the vertical surface of a wall, such as in a hall or conference room, as distinguished from the bottom-mounted luminaire shown. Referring now to FIG. 4, the end cap 17 is seen in detail. It is received on and held to an intermediate wall 53 which serves to mount the lamps and also to support a ballast B in the manner illustrated. Thus, the end cap 17 cooperates with the intermediate wall 53 to provide a housing for the ballast B which may be mounted by means of a flexible grommet 55 to a platform 56 cantilevered from the intermediate wall 53 to reduce noise transmission from the ballast B.

In FIG. 4, there is also shown a gasket 58 which seals the left edge of the lens 41 against the entry of dust into the interior of the luminaire. A similar gasket is provided on the other intermediate wall 40.

Turning now to FIG. 5, which illustrates the structure of one side of the lens 41 in relation to the center of lamp L1, designated 60 in FIG. 5, the top portion 48 of the lens has a flat upper surface designated 61. This facilitates dusting of the fixture and provides no crevices for collecting dust or dirt. The under surface of the top portion 48 of the lens 41 is formed into a plurality of equilateral prisms 62 which extend the length of the lens, and are separated by flat portions or simply "flats" designated 63.

The principal function of the prisms 62 is to cause incident light to diverge through refraction. Consider, for example, parallel incident rays 65, 66 which are incident respectively on the surfaces 62A and 62B. The ray 65 is refracted and travels along the path 67 through the transparent material of the lens to the upper exit surface 61 thereof where it" is again refractέ-d and travels along the divergent path 68. Similarly, the ray 66 follows the path 69 in the lens and emerges along the path 70 from the exit surface 61. Thus, the light which is incident on the surfaces of the prisms 62 is widely dispersed and diverged through refraction.

Light which is incident on one of the flats 63, on the other hand, is simply displaced but remains parallel to the path of the original incident ray. Consider, for example, the ray 72 which is incident on a land designated 63 A. It travels along a path 73 within the lens material, but emerges from the exit surface 61 to travel along a path 74 which is parallel to the path of the original ray 72. Because of the size, configuration and spacing of the prisms, the light emerging from the exit surface

61 is diverged in such a manner that the resulting pattern of luminance on a horizontal surface above the luminaire for as close a spacing as one foot is substantially uniform without either bright or dark areas.

In a preferred embodiment, the angle of each of the prisms

62 is 60 degrees; and the height is 30 mils. The spacings of the prisms is 62 mils, and the thickness of the lens 41 between the exit surface 61 and the flats 63 is 130 mils. These dimensions can be changed without any appreciable change in the results. If the proportion of prism height to spacing remains the same, the results will be the same. The material of the lens preferably is clear virgin acrylic, although other materials such as Lexon may also be used.

Turning now to the lateral portion 50 of the lens, its principal function is to bend incident light from the source and to "fan" the light out laterally so that it is spread to the side of the fixture on a ceiling and may also be used to illuminate any vertical surfaces in the neighboring vicinity. Because of the reduction in intensity due to the greater distance traveled by the light passing through the lateral portion 50 as well as the fact that the flux will be spread over a greater area of any illuminated horizontal surface due to the increased angle of incidence, a principal function of the reflector 30 and particularly the curvature of the portion 36 is to direct light from the source L1 toward the lateral portion 50 of the lens.

The lateral portion 50 of the lens has a uniformly curved, smooth interior surface 80 which has a radius of curvature centered at 81. The outer surface of the lateral portion 50 of the lens is formed into a plurality of prisms, the points of which are designated respectively P1-P21 for convenience.

Each of the prisms P1-P21 includes an active or emitting surface such as that designated 84 for the prisms P3 from which light incident on the inner surface 80 will emerge, and a second surface 85 referred to as a riser or return surface. The structure of the prisms P1-P21 is illustrated in Table I where the an les RHS LHS LHS-1 and LHS-2 are defined in FIG. 5. dimension "h" is the height of a prism. The nominal thickness of the lateral portion 50 from the uniformaly curved surface 80 to the intersection between an adjacent riser 85 of one prism and the active surface of the adjacent prism is 125 mils. Further, the center 60 of the light source is approximately 0.625 inches below the center 81 of the radius of curvature of the surface 80_/ and approximately two inches to the left of it. It will also be observed that the center 81 is in approximately the same horizontal plane as the upper extension of the curved side 22 of the opaque housing 15. Thus, the light sources cannot be seen directly by an observed eye level is the same height as the source .

Because the luminaires are preferably mounted at a height of six to seven feet above the floor (that is, the height to the top of the side wall 22 of the housing 15), a person who is less than about seven feet tall will have a line of sight which will be above the lamps. However, as will be explained presently, he will perceive where the light is coming from.

Still referring to FIG. 5, three light rays are designated 90, 91 and 92; and for purposes of illustration, they are shown as emanating from the center 60 which is an idealized point. In the medium of the lens, the rays take the respective paths 90A, 91A and 92A; and when they exit from the associated active surfaces of the prisms as illustrated, they travel along the paths 90B, 91B and 92B respectively. It can thus be seen that the light from the source is spread out in an increasing pattern from the top to the side edge of the lateral portion 50 of the lens. Further, it is segmented in the sense that an observer viewing the lens from the side at normal angles will see a series of softly glowing horizontal lines and therefore perceive where the light is emanating from. Not illustrated in FIG. 5 for clarity are the rays of light emanating from the source L1 which are reflected by the reflector 30 and directed toward the lateral portion 50 of the lens. As indicated, these rays reinforce the direct rays from the source so that the pattern of luminance on a horizontal surface above the fixture will be substantially uniform and without glare spots or dark areas not only directly above the luminaire

. but also for a distance of several feet to the side thereof. By providing uniform ambient lighting, as mentioned, above, the overall luminance can be maintained at a relatively low level and yet provide adequate task lighting. By bending the light and fanning it out laterally through the lateral portions of the lens, the luminaires can be placed at relatively greater distances than would otherwise be required to achieve complete illumination coverage and uniform luminance. Vertical surfaces in a room employing these luminaires are also illuminated in a substantially uniform manner even at eye level and above, because of light direct from the lateral lens portions and reflected off the ceiling. As mentioned, human perception of whether a room is adequately lighted depends to some extent on whether the vertical surfaces are visibly illuminated.

Still further, it will be appreciated that the lens act as a dust cover to prevent dust and dirt from reducing the luminance emanating from the source, and because the upper surface of .the top portion of the lens is flat, it facilitates cleaning. It will be observed that at least some light emanates from the riser surfaces of the prisms on the lateral portion of the lens, and this light is directed downwardly below the horizontal. It may not be enough light to provide adequate task lighting but it nevertheless provides a visual image to an observer seated at a work area so that he can see where the light is coming from.

Having thus described in detail a preferred embodiment of the invention, persons skilled in the art will be able to modify certain of the structure which has been illustrated and substitute equivalent elements for those disclosed while continuing to practice the principle of the invention. For example, the dimensions of the lens may be altered without substantially changing the photometric properties of the luminaire, particularly, if the height-to-spacing proportions of the various prisms is maintained. Further, although fluorescent lamps are preferred, other lamps may also be used; and lamps not yet developed may have equal or better results. Finally, the number of lamps or type of ballast are not critical to achieving the overall desired results. It is, therefore, intended that all such modifications and substitutions be covered as they are embraced within the spirit and

Claims

The Claims

1. A luminaire for indirect lighting comprising a source of light, opaque housing means extending upwardly about said source, a lens above said source including an upper light-dispersing portion receiving light from said source and diverging it upwardly to provide a substantially uniform luminance pattern on a horizontal surface above said luminaire, said lens further including a lateral light-bending portion receiving light from said source for fanning out said light laterally of said housing to continue said substantially uniform luminance pattern to portions of said horizontal surface not directly over the luminaire, and to illuminate vertical surfaces in the vicinity of the luminaire; and reflector means for reflecting light from said source and directing it to said lateral portion of said lens.

2. The apparatus of claim 1 wherein the upper portion of said lens includes a plurality of prisms extending longitudinally of said luminaire for the length of said light source and a flat surface extending between adjacent ones of said prisms.

3. The apparatus of claim 2 wherein said prisms are located on the interior surface of said lens and the exterior surface of the upper portion of said lens is free of crevices to facilitate cleaning.

4. The apparatus of claim 3 wherein said prisms on said upper lens portion are substantially equilateral prisms for dispersing incident light and flat portions displace but do not diverge incident light; and wherein said flat portions are parallel to the exterior surface of the upper portion of said lens.

5. The apparatus of claim 4 wherein said prisms have a height-to-spacing ratio of approximately 0.030 to 0.062.

6. The apparatus of claim 1 wherein said lens is made of clear virgin acrylic plastic.

7. The apparatus of claim 1 wherein said lateral lens portion includes a plurality of prisms extending lengthwise of said lens substantially the length of said source and characterized in bending incident light rays toward the horizontal.

8. The apparatus of claim 7 wherein said lateral lens portion has an interior curved surface having a radius of curvature smaller than the distance between said curved surface and said source.

9. The apparatus of claim 8 wherein the prisms of said lateral lens portion define 21 points and are defined in accordance with Table I.

10. The apparatus of claim 1 wherein said lens is made clear acrylic and includes at its lower, outer edges first and second elongated fittings, said housing defining inwardly extending lips at its upper edges for receiving said fittings of said lens.

11. The apparatus of claim 1 wherein said light source includes two fluorescent lamps and said lens includes first and second lateral light-bending portions symmetrical about a vertical plane passing between said light sources.

12. The apparatus of claim 1 further comprising first and second end caps connected to said housing, and a ballast for said lamps secured in one of said end caps.

13. The apparatus of claim 1 further comprising means for mounting said luminaire to a movable wall panel at a height in the range of six to seven feet.

14. A luminaire for indirect lighting comprising a source of light, opaque housing means beneath said source and extending upwardly about said source to hide said source from view through a horizontal line of sight even with said source, and a lens above said source including an upper light-dispersing portion receivi light from said source and diverging it upwardly to provide substantially uniform luminescence to a horizontal surface above said luminaire, said lens further including a lateral lightbending portion receiving light from said source for fanning out said light externally over said housing to continue the uniform illumination of said horizontal surface not directly over the luminaire, and to illuminate any vertical surfaces in the vicinity of the luminaire.

15. The apparatus of claim 14 further comprising means for mounting said luminaire to the top of a movable wall panel.