Strip lighting

Abstract

 A housing assembly for strip lighting is provided including an elongate housing (14) for disposing light sources (8) and which is at least partly of a translucent material, which housing (14) is a hollow enclosure and defines a passageway extending longitudinally of the housing, a mounting rail (30), and co-operable longitudinally extending formations (27a, 27b, 32a, 32b) on said rail (30) and on said housing (14) for effecting a snap or sliding engagement of the housing (14) to the rail (30) so that the housing (14) is generally parallel to the rail (30).

Description

FIELD OF INVENTION

[0001] This invention relates to light sources and to lighting systems, and has a particularly advantageous application to the decorative illumination of structures and structural elements. The invention is especially effective when employed with LEDs as light sources, although it is emphasized that broader applications are encompassed.

BACKGROUND OF THE INVENTION

[0002] British patent publication 2102933 discloses a lighting display configuration made up of multiple transparent polycarbonate or plastics tubes linked by socket units with several differently oriented recesses to seat the tubes. Each of the tubes contains an array of light bulbs, filament lamps or light emitting diodes (LED). The application illustrates a free standing framework of the tubes and linking socket units.

[0003] A known lighting product in strip form has a linear array of well-spaced LED chips in a close-fitting colored plastics tube of rectangular cross-section. The tube is a little less than 1 cm in width and each LED chip is visible from the exterior both when not activated and as an individual point of light. The product is used to provide low light level safety lighting, e.g., as a front edge "night light" marker for steps and stairways, and thus the rectangular tube is a protective carrier housing for the low light level LED marker lamps.

[0004] Another known product has small incandescent light bulbs embedded at intervals in an axial plane in a solid cylinder of plastics material. The bulbs are arranged as series sets in parallel, electrically connected across a pair of longitudinally extending wires also embedded in the cylinder. Each bulb stands out individually when the device is activated, so that the cylinder of plastics material effectively serves as a carrier forming a chain of spaced incandescent bulbs.

SUMMARY OF THE INVENTION

[0005] The present applicant has appreciated that a light tube structure in which multiple light emitting diodes are arranged within an elongated translucent tube, provides a wide variety of opportunities for novel strip lighting of structures such as playgrounds and the walls and roofs of commercial premises including restaurants. This opportunity is further enhanced by the recent availability of light emitting diodes of substantially enhanced luminance relative to conventional devices, and of multi-color LED devices.

[0006] The invention provides for the fixing of translucent housings containing spaced LEDs on wall or frame surfaces of a wide variety of structures.

[0007] In a particular application, the invention is directed to a structure having one or more features highlighted or decorated by one or more of the above-described strip lighting devices.

[0008] Preferably, the highlighted or decorated feature of the structure is a corner or edge, for example an edge of a roof, a window or a door, or a corner between respective wall or roof sections. A particularly effective application is to a gable or ridge line of a building roof. The strip lighting device(s) may be mounted along the edge or corner or adjacent to but offset from the edge or corner.

[0009] The housing of the strip lighting device may be substantially white, but is preferably a color other than white. In one application of the invention, the structure is a commercial building and the color of the or each housing is chosen to match or complement the color(s) of identification or trade mark signage displayed on the building.

[0010] The highlighted or decorated feature may alternatively be, e.g., a post, a rail or a border.

[0011] A mounting means is provided that includes a mounting rail adapted to be fastened to said surface, and cooperable means on the strip and the housing for effecting a snap or sliding engagement of the housing to the strip so that the housing is generally parallel to, and preferably overlies, the strip.

[0012] The light sources are preferably light emitting diodes or other low voltage or semi-conductor devices.

[0013] The invention provides a housing assembly for strip lighting, including:

an elongate housing at least partly but preferably substantially wholly of a translucent material, which housing is a hollow enclosure and defines a passageway for disposing light sources extending longitudinally of the housing;

a mounting rail; and

co-operable longitudinally extending formations on the rail and the housing for effecting a snap or sliding engagement of the housing to the rail so that the housing is generally parallel to, and preferably overlies, the strip.

[0014] The snap or sliding engagement may be achieved between longitudinally extending rib means on one of the components, preferably the strip, and complementary groove means on the other. There may be opposed longitudinal undercut formations in the groove means.

[0015] The strip conveniently includes a substantially planar rear engagement with the respective surface to which it is fastened.

[0016] Preferably, in all of the aforementioned aspects of the invention, the outer or front face of the elongate hollow housing is defined by a transversely domed or convex segment.

[0017] Preferably, in all the aforementioned aspects of the invention, the interior of the housing is provided with support means for one or more webs or strips extending longitudinally of the housing. One such web or strip may be a support web for the light sources and for the electrical connections to these light sources, and may thereby incorporate ribbon cable. A suitable support web is printed circuit board (PCB) laminate. The web or strip may be transversely oriented at any angle, e.g. parallel to or normal to the backing surface, or otherwise. The light sources may be on either face or side of the support web or strip, or on both faces or sides.

[0018] Connector means is preferably provided to physically couple a pair of the elongate housings whereby the housings may be relatively longitudinally displaced in situ, egg. by thermal expansion or building subsidence, without being uncoupled. Where the light sources are provided on a plurality of support webs or strips having electrically conductive surface elements and extending longitudinally of the housings, connectors are preferably also provided for pairwise electrically and physically coupling the support webs or strips whereby the webs or strips may also be relatively longitudinally displaced in situ without being uncoupled, either physically or electrically. It is particularly advantageous to provide for such displacement both between housings and between support webs or strips carried by an array of the housings.

[0019] A further said strip or web may be an optical refractor or diffuser, arranged in front of or behind the light sources as appropriate.

[0020] In all aspects of the invention the housing may be hollow and/or may define a passageway in which the light sources are disposed. Alternatively, the housing may be substantially a solid, e.g. moulding about the pre-positioned light sources, or with cavities to receive the light sources.

[0021] Where the elongate housing is hollow, it is preferably a plastics (e.g. polycarbonate) extrusion of substantially uniform cross-section, and is preferably translucent but not transparent. A translucent and also transparent housing may be preferred in some embodiments. The housing can be substantially rigid. A suitable form of the flexible tubular segment is a collapsible pleated web or concertina structure.

[0022] Presently, the base strip, flexible tube segments and coupling means are also at least partly provided in translucent material.

[0023] The means to diffuse, disperse or scatter may include e.g., a body portion of the housing, and/or light diffuser means in the passageway.

[0024] The invention may also provide a connector for physically coupling a pair of generally tubular components, including:

an integral moulded body which defines a pair of generally tubular portions slidably engageable with the respective said tubular components so that their interiors are in communication within the connector;

wherein said integral moulded body further defines a relatively thin wall portion between said generally tubular portions, said thin wall portion being resiliently deformable to compensate for relative variations in the relative positions of the generally tubular portions.

[0025] The material of the body is preferably silicone rubber or similar.

[0026] There may also be provided a connector for electrically and physically coupling a pair or more of support strips having electrically conductive surface elements including:

an integral moulded body with features which define spaced generally parallel channels or passages open at their outer ends to receive respective end fingers of the respective said strips, whereby the strips are aligned and generally co-planar;

electrically conductive contact means in said channels or passages for engaging complementary contacts on said strips when said fingers are received in the channels or fingers;

means carried by said body electrically connecting each of the contact means for one strip carried by said body with one or more of the contact means for the other strip; and

resiliently deformable means on said body for latching said body to each of said strips.

[0027] Preferably, each of the electrically connecting means is provided contacts as an integral electrically conductive strip - more preferably, the strip is of appropriately conductive material, e.g. phosphor-bronze or other alloy, mounted to be resiliently deflected by said fingers.

[0028] Preferably, the spaced channels are arranged along opposite sides of the integral moulded body, and open laterally from the body. In an embodiment, these channels are provided in elongate side portions linked by a central cross-piece in an I or H configuration.

[0029] The resiliently deformable latch means is preferably provided as a pair of deflectable tongue portions with lugs, which tongue portions is defined by slits in a web portion of the integral moulded body, e.g. bridging said elongate side portions of the body.

[0030] In still further aspects, the invention respectively provides (i) a strip lighting system including multiple strip lighting devices as described above, and (ii) a set of components for such a system including multiple such strip lighting devices, flexible tube segments, and suitable coupling means such as, e.g., connectors according to the aspects of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

[0031] The invention will now be further described, by way of example only, with reference to the accompanying drawings, in which:

Fig. 1 is a perspective view of a simple arrangement of a strip lighting system incorporating multiple light source enclosures according to an embodiment of the invention, depicted on the wall of a restaurant or other premises;

Fig. 2 is an end element depicting a light tube segment and mounting rail ready for engagement;

Fig. 3 illustrates an advantageous application of the strip lighting system to the illumination of the roof lines of a building, according to an embodiment of the invention;

Fig. 4 illustrates an application of the invention to the framing of a display signage unit;

Fig. 5 is a fragmentary cross-section of part of the unit of Fig. 4;

Fig. 6 is a perspective view of a form of connector for coupling two light tube segments;

Fig. 7 is a fragmentary cross-sectional view of the connector of Fig. 6 in situ;

Fig. 8 is an isometric view of a connector for coupling the cable ribbon support strips, being an embodiment of the invention;

Fig. 9 is a side elevational sketch of the connector shown in Fig. 8, with support strips inserted into position;

Fig 10 shows an end portion of a support strip slit to co-operate with the connector of Fig. 8;

Fig. 11 is an axial cross-section of an end-insert;

Fig. 12 is a cross-section on the line 12-12 in Fig. 11;

Fig. 13 is an outer end-elevation of the end-insert;

Fig. 14 is an axial cross-section of a flexible tube segment for linking light tube segments where they are not aligned;

Figs. 15 and 16 are an end-elevation and an axial cross-section of a locking ring;

Fig. 17 is a cross-section on the line 17-17 in Fig. 16;

Fig. 18 is a fragmentary cross-section illustrating the assembly of a pair of substantially rigid light tube segments to an intervening flexible light tube segment of the form shown in Fig. 14;

Figs. 19 and 20 depict two views of an end plug;

Fig. 21 is a cross-sectional view showing termination of a light tube segment by an end plug;

Fig. 22 depicts, in section, an elbow;

Fig. 23 shows an alternative form of end-cap;

Figs. 24 and 25 illustrate, in isometric and cross-sectional views, a further alternative arrangement for interconnecting two of the tube segments end to end; and

Fig. 26 is a sectioned isometric view of a modified tube and rail assembly.

DETAILED DESCRIPTION

[0032] Referring firstly to Figures 1 and 2, the illustrated strip lighting system 10 includes several light source enclosures 12 each having an elongate hollow housing 14 of a translucent material. Housings 14 are hereinafter referred to as light tube segments. These segments 14 are straight and substantially rigid, and are linked by flexible segments 16. Light tube segments 14 define respective internal passageways 13 in which multiple light sources in the form of light emitting diodes (LED) 8 are arranged at intervals on ribbon cable support strips 9, e.g. printed circuit board (PCB) laminates. These laminates may be of either substantially rigid or flexible type. The LEDs are preferably of the surface mounted type. The electrical conductor cables printed on these strips are electrically connected to an external power source/controller via junction boxes and upright cable enclosures 22. The PCB laminate or other support strip may include local or extended layering or coating to provide an optical effect, e.g. reflection, in cooperation with the LEDs.

[0033] Light tube segments 14 are fixed to respective surfaces 5 of a structure 6 so that they each extend along and adjacent the surface, by base strips in the form of mounting rails 30 onto which the tube segments 14 can be releasably snap fitted. The mounting rails 30 are in tum fixed onto the surfaces 5 by screws or the like hidden by the attached tube segments.

[0034] Other components of the illustrated strip lighting system include end inserts 40 for providing tube segments 14 with end coupling formations, end plugs 50 (Figure 4) for terminating the light tube segments other than at junction boxes, and locking means 60 for disengagably coupling inserts 40 to the flexible tube segments 16 or to the end plugs 50.

[0035] Each substantially rigid light tube segment 14 comprises an extrusion of uniform cross-section in a plastics material selected so that it is translucent in a manner whereby to diffuse, disperse or scatter the light emitted by the interior LEDs, so that the tube appears to glow when viewed from the outside. In this way, an extended strip or line of light is provided, i.e. the tube appears to glow over a substantially continuous zone extending over its length and encompassing the contained light sources. The translucent material is preferably such that the LEDs are not visible to the eye when not activated and viewed from outside the housing, and are substantially not distinguishable when activated and viewed from outside the housing.

[0036] A suitable material is a polycarbonate polymer composition with appropriate color pigment and a titanium dioxide whitening agent to determine the optical dispersion and degree of translucence or opaqueness. The color may be chosen to match a color of the LEDs, or may be any other color, or white or colorless. The color is preferably UV stabilized. In an alternative embodiment, the material of the extrusion may contain dispersed light scattering elements such as metal shavings or chips, or dust, that are effective to diffuse, disperse or scatter the emitted light and so cause a sparkling effect. In a still further variation of the tube segment, diffusion, dispersal or scattering of the LED light may be facilitated by the presence of fine grooves, ribs or other surface variations in the extruded segment. The extrusion material may include a component which is optically activated by electromagnetic radiation such as the sun's light or other radiation so that the emitted color, pattern or other optical characteristic may be altered.

[0037] A cross-section of the extrusion is illustrated in Figure 2. It includes a semi- S circular or semi-annular outside portion 23, generally straight side wall portions 24a, 24b, and a slightly flared thin-wall base structure 25 in which a pair of hollow longitudinally extending ribs 27a define a central groove or channel 27. Channel 27 has shallow undercuts 28a, 28b along each side defined behind rounded ridge portions 29a, 29b.

[0038] The interiors of side wall portions 24a, 24b of light tube segment 14 are provided with a number, typically four as illustrated, of longitudinally extending ribs 19a that are evenly spaced to define intervening grooves 19b. These grooves are provided for mounting ribbon cable strips 9, or optical diffuser or reflector strips or other accessories. This will be discussed further below.

[0039] Each mounting rail 30 is also an elongate extrusion of uniform cross-section formed in a material similar to light tube segments 14. It has a main base web 31 with two integral outstanding ribs 32a, 32b of shallow V configuration in cross-section. The lateral outside profile of this strip is thereby a close match with the side profiles of channel 27, including a V-groove 34a, 34b matching ridge portions 29a, 29b and a rib formation 35a, 35b matching undercuts 28a, 28b.

[0040] The mounting rail 30 is dimensioned to be an interference fit in channel 27. The hollow thin-wall form of tube segment base structure 25 and the arrangement of ribs 32a, 32b on mounting rail 30 allow both components to flex and deform so that the tube segments 14 can be demountably attached to the mounting rails by pressing the tube segments onto the mounting rails in the direction of the arrow 80 in Figure 3. The ribs 32a, 32b flex inwardly towards each other and the hollow flanges 26a, 26b of the tube flex apart to allow the rib formations 35a, 35b to snap past ridges 29a, 29b into undercuts 28a, 28b. In this way, the light tube segment can be mounted to a surface such as a wall surface by first fixing the mounting rails in place against the wall with fasteners 100 driven through the main web 31 of the rail, and then snapping the tube segment into place. Mounting rails 30 have a smooth flat rear face 33 for engaging the wall or outer surface on which the rail is mounted, and the fasteners are hidden from view in the assembled configuration. The mounting rails may include provision to support electrical conductors in particular applications. If it is desired at any time to rearrange or dismantle the strip lighting, tube segment 14 can be grasped and pulled off the mounting rails by inverting the snap action. To facilitate the snap-fit, there may be a longitudinal slit in the center of channel27, at the position indicated in Figure 2 at 127.

[0041] It will be appreciated that the illustrated system is adaptable to provide configurations of strip lighting which match or complement a structure or provide a particular shape, e.g. a recognizable shape. An advantageous application is illustrated in Figure 3. A building 150, e.g. a commercial premises such as a restaurant, includes a roof 152 with peripheral edges 153 and corners such as ridge line 154 or gables 156. Certain of these edges and corners are fitted with light tube segments 14 to form a strip lighting system for the roof. The strip lighting system thus highlights and decorates the respective features of the roof. The color of the tube segments may be chosen to complement the color scheme of the building and/or to match the color(s) of identification or trade mark signage displayed on the building. It will of course be understood that the strip lighting system may be applied with similar effect to other building lines, both internal and external.

[0042] With good choice of LED characteristics, color and spacing, the effect of the strip lighting system on the building as illustrated in Figure 3 is to enhance the profile of the roof line without creating glare, and without being unduly ostentatious. The light has a richness without excessive brightness. Undesirable dark spots are eliminated or reduced. Major electrical switchboard adjustments are avoided, and the inventive system does not include the inconvenience, high maintenance and fragility of neon tubes. Fixings are concealed and easy to install, and protruding structure, which might attract birds, is avoided. Very long continuous lines of light can be achieved, whereas neon tubes require regular interruption by discharge boxes.

[0043] In a variation, mounting rails 30 may have an integral leg or rib, e.g. T, L, or X section, for elevating the rail from an edge or surface. Twin rail extrusions may be provided. These variations may assist in e.g. positioning tube segments 14 as framing for surface mounted features. Figure 4 illustrates the application of the strip lighting to a promotional display sign, and Figure 5 is a sectional view showing the T-section leg 129 of mounting rail. This highlights the application of the invention to shopfitting generally. Other applications include playgrounds e.g. to highlight posts or rails, and children's locations in general. In alternative applications, the mounting rail may be free-standing.

[0044] Figures 6 and 7 depict an embodiment 100 of connector for coupling a pair of tube segments 14 to form a longer strip of light for applications such as that depicted in Figure 3. This connector is simple in form yet effective in adjusting for relative movement between the tube segments, e.g. due to thermal expansion or contractions. Connector 100 is an integral generally tubular moulding in liquid silicone rubber which consists of a pair of substantially identical socket portions 102, 103 linked by a relatively thin walled center portion 104. Each socket portion 102, 103 has an internal profile to closely match the external profile of tube segments 14 so that each is slidably engageable with and about an end of a respective tube segment 14 so that the interiors of the tube segments are in communication within connector 100.

[0045] At their inner ends, each socket portion 102, 103 has an internal flange 106 that defines a peripheral groove 107 to receive and sealingly grip the end 14a of the tube segment. Centre portion 104, bridging the two flanges 106, is sufficiently thin to be able to accommodate or compensate for relative movement of the tube segments without uncoupling of the tube segments, by resiliently buckling, stretching or otherwise deforming. Further compensation is provided by sliding movement of the tube segments longitudinally of groove 107. The material of the connector should be chosen to facilitate and optimize this role. Liquid silicone rubber (LSR) is especially suitable, because of its excellent elastic memory in deformation, its ability to sealingly grasp the tube segments, and its overall durability. The moulding thus achieves a substantially waterproof coupling with structural integrity, able to compensate for thermal expansion and other displacement between the tube segments 14.

[0046] Figures 8 and 9 illustrate an embodiment 110 of connector for electrically and physically interlinking ribbon cable support strips (typically PCB laminates) 9 within tube segments 14, or within a coupling between them.

[0047] Again connector 110 is an integral moulding in a suitable material. The moulding defines a solid body comprising spaced parallel elongate side portions 112, 113 linked by a central cross-piece 114 in an I or H configuration. The bights within this body are closed by generally rectangular web portions 116, 117. Along the outside of side portions 112, 113 are respective channels 118, open laterally of the connector. Each channel is divided by a center block lug 120. Mounted against top and bottom of each channel is a respective spring metal strip 122 (e.g. of phosphor bronze, not shown in Fig 8) shaped to pass over lug 120 and under intermediate lugs 124, and retained by slots 126 in end ribs 128. The ends of channels 118 are open, between ribs 128, to receive respective end fingers 140, 142 of PCB laminates 9 (Figure 10). These fingers force contact strips 122 resiliently apart, so ensuring electrical contact with contacts 144 on the top and bottom faces of the strip fingers.

[0048] The PCB laminates 9 are latched to the connector by engagement of lugs 132 in matching apertures 145 (Figure 10) in the laminates. Lugs 132 are provided on resiliently deflectable tongues 130 defined in the open edges of web portions 116, 117 by slots 134. Lugs 132 have an inclined outer strike face 135 by which the strip forces the tongue/lug pair aside, and a steep inner face 136 which provides the latching function. Tongues 130 can be deflected manually to uncouple the components.

[0049] Connector 110 would typically include a formation (not shown) to prevent coupling except in a correct relative strip orientation. Connector 110 is also preferably such as to allow relative longitudinal displacement of the respective laminates, e.g. between limits determined by co-operating abutments without their being uncoupled either physically or electrically. Connector 110 is preferably designed and colored to minimize disruption to the uniformity of the light pattern emitted by the connected tube segments.

[0050] A set of the various components described and illustrated herein may be delivered to a site and mounted to a structure or set of walls in the manner described. Connectors 110 would be used to bridge the diode mounting strips via the interiors of the flexible tube segments 16, and electrical power would be delivered to the diodes via upright cable enclosures 22 and junction boxes 20 (Figure 1) to which at least some of the tube segments 14 would be attached. Advantageously, the light levels of multiple tube segments could be controlled at a central point to achieve balance, or to obtain particular effects. In another alternative arrangement, each tube segment or respective subgroups of tube segments may have a separate brightness control, e.g. a current level adjustment device mounted in the tube segment or adjacent mounting rail.

[0051] It will be appreciated that the light emitting diodes may be of any suitable type, e.g. the three-color diode sets now available, but it is desirable to avoid excessive variations in outputs between diodes for a given current, and to seek long life LED products. The LEDs could be simply activated to provide constant and uniform illumination, or could be managed in a variable sequence by programmed logic circuits either internal or external to the illustrated configuration. By similar means, random and variable patterns, color and hue variations and color changes can be achieved.

[0052] Because the connectors 100 allow a degree of relative longitudinal movement between adjacent coupled tube segments 14, and the connectors 110 perform a similar function between adjacent coupled PCB laminates 9, the system is able to simultaneously compensate for or accommodate such dual movement, e.g. due to thermal expansion or building subsidence, both externally in the array of tube segments 14 and internally in the contained array of PCB laminates. Provision for such compensation is advantageous in most "real-world" applications of the inventive concepts.

[0053] As already noted, light tube segments 14 may be fitted with end inserts 40 to allow them to be connected to other fittings. A typical such insert is illustrated in Figure 11 to 13. It is an integral moulding in a suitable plastics material, preferably that used for segments 14 and 42 and mounting rails 30. The insert essentially includes three axially successive portions, i.e. a plug portion 42, an end flange 44 and a connector portion 46. Plug portion 42 is precisely matched to make an interference fit into either of the open ends of a light tube segment 14 and thus has an external profile complementary to the internal profile of tube segments 14. The interior of the insert is provided with a peripheral shallow shoulder 29a at the transition between plug portion 42 and flange portion 44, and with a longitudinally extending convex rib 29b at the top interior of plug portion 42. These features are for locating and keying electrical cable ribbon connectors as and if required.

[0054] End flange 44 is a lateral enlargement about the whole of plug portion 42 and has an external profile which closely matches that of each tube segment 14. It may thus also be snapped onto a base strip 30 if needed at an intermediate position on the base strip.

[0055] Connector portion 46 is a generally tubular coaxial extension from flange 44 having two additional features at its outer axial end: an external flange 47 and a peripherally extending frustoconical enlargement 48 of the internal bore 45. This enlargement is to provide an 0-ring seat, as will be further explained. The flange 47 locates a locking ring 60.

[0056] An assembled tube segment 14 for installation would be fitted with at least an array of light emitting diodes 8 mounted on a suitable cable ribbon support strip 9. Typically, this strip would be mounted in a lower pair of grooves 19b. If desired for particular effects, a suitable diffuser strip may be mounted in another of the groove pairs, or a refractor strip may be mounted in a still further pair, typically between the light emitting diodes and the diffuser strip relative to the curved front of the tube. Once these are in place, they can be retained by fitting inserts 40 to either or both ends of the tube and fixing them in place with a suitable adhesive or contact cement at the interface between plug portion 42 at the internal surface of the tube. Other fixing and closure arrangements are of course possible.

[0057] The orientation of the plane of strip 9 may be varied in other embodiments. For example, this plane may be normal to surface 5 in Figure 2. Moreover, LEDs 8 may be on either or both surfaces of strip 9.

[0058] A flexible tube segment 16 is shown in situ in Figure 1 and detailed in Figures 14 and 18. Flexible tube segment 16 is a thin walled moulding of a translucent material similar to that of tube segments 14. The general structure is of a corrugated or pleated configuration by virtue of which the segment is highly flexible and able to be compressed concertina - fashion, bent along its axis through 90° or more. The segment is provided with end portions 84 which include a tapered spigot 85 and a pair of diametrically opposite arcuate lugs 86 which are set back from tapered end portion 85 so that a very shallow reversely- facing annular shoulder 88 at the inner end of spigot portion 85 defines an 0-ring seat 89 between it and lugs 86.

[0059] A further component for effecting coupling of the flexible tubular segments 16 to the rigid tube segments 14 is integrally moulded locking ring 60 (Figures 15 to 17). This essentially consists of a bayonet socket ring 62 and a snap fit half ring 64 with an undercut 65. The outer surface of the ring has integral grip-enhancement ribs 63. Bayonet socket ring 62 has diametrically opposite arcuate recesses 66 that are matched to receive lugs 86 of flexible tube segments 16. The snap fit half ring 64 is slightly larger than semi-circular, subtending at its outer rim about 250° and extending between deformable wings 67a, 67b.

[0060] With reference now to Figure 18, which depicts in cross-section an assembly of a flexible tube segment 16 with tube segments 14, the locking ring 60 is applied to the body of insert 40 behind flange 47: the wings 67a, 67b deform apart so that the locking ring snaps about the body of the insert and is then retained by engagement of flange 47 behind undercut 65. The end formation 84 of a flexible tube segment 16, with the 0-ring 90 in seat 89, is then introduced into the locking ring by passing lugs 86 through recesses 66. On twisting of either component, the 0-ring 90 held in seat 89 is clamped against frustoconical end surface 48, thereby clamping all of the components together to form the assembly shown in Figure 18. The joint is preferably liquid tight and/or gas tight, especially if the system is intended for outdoor installation.

[0061] Instead of coupling a tube segment 14 to another tube segment 16, the former may be terminated by means of end plug 50 (Figure 19 to 21). End plug 50 has an end formation 51 similar to end portion 84 of flexible tube segment 16, including a spigot portion 55, shoulder 58 and 0-ring seat 59. However, in this case, the interior is closed by a transverse membrane 52 flush with the spigot end of the plug, and the component is completed by an external flange 54. Assembly to an end insert 40 using a locking ring 60, and clamping an 0-ring 90, is similar to that described above for the flexible tube segment and is depicted in Figure 19.

[0062] End inserts 40 can also be employed to couple a pair of tube segments to the respective ends of a tubular elbow component 220 (Figures 4, 22) defining a selected angle bend between the two segments. This component may be rigid or flexible, and may conveniently also be formed in the aforementioned liquid silicone rubber (LSR).

[0063] An alternative to end plug 50 is depicted in Figure 23, and consists of a LSR end cap 250 that fits onto end insert 40 and may include a port 252 for a cable 254 or other accessory. This allows an effective watertight seal around the cable.

[0064] An alternative coupling arrangement is shown in Figures 24 and 25. Here, the tube segments 14 are closed by polycarbonate end caps 200 with ports 201 for conductor pins 202. These pins 202 are held in a liquid silicone rubber coupler 204 shaped, like connector 100, to the profile of the tube segments. Coupler 204 has central bosses 206 that retain the conductor pins 202 and project into and seal ports 201. Coupler 204 embraces and grasps the respective end caps 200.

[0065] The illustrated embodiments- with the enclosed tubes 14, 16, separate mounting rails 30 and various forms of coupling - provide a strip lighting system in which the LED's are protected in an environment which is able to be sealed against moisture incursion, but is easily installed and dismantled. The installation may thus be substantially permanent or only temporary. Tubes may be readily detached individually for service of the electrical componentary, e.g. replacement of failed diodes.

[0066] The component bodies - tube segments 14, 16, mounting rails 30, external connectors 110, end inserts 40, locking ring 60, and end plugs 50- may be provided in a single uniform color, or in any other color configuration. By forming all of the components in translucent optically diffusive material, advantageous continuity of the strip lighting can be achieved. Variations of intensity are easily obtained with choice of material and internal LED configuration or control. In an alternative arrangement, the tube segments 14 and the mounting rails 30 may be extruded in quite different colored materials. In a still further variation, illustrated in Figure 26, the tube segments 14 may be separable into base 14a and cap 14b portions of different colors and/or materials.

Claims

1. A housing assembly for strip lighting, including:

an elongate housing (14) at least partly of a translucent material, which housing (14) is a hollow enclosure and defines a passageway for disposing light sources (8) extending longitudinally of the housing;

a mounting rail (30); and

co-operable longitudinally extending formations (27a, 27b, 32a, 32b) on said rail (30) and on said housing (14) for effecting a snap or sliding engagement of the housing (14) to the rail (30) so that the housing (14) is generally parallel to the rail (30).

2. A housing assembly according to claim 1 wherein, on said engagement, the housing (30) overlies said rail (14).

3. A housing assembly according to claim 1 or 2, wherein said snap or sliding engagement is between longitudinally extending rib means (32a, 32b) on one of the components, and complementary groove means (27) on the other.

4. A housing assembly according to claim 3 further including opposed longitudinal undercut formations (28a, 28b) in said groove means.

5. A housing assembly according to any preceding claim wherein said elongate housing (14) is a plastics extrusion of substantially uniform cross-section.

6. A housing assembly according to claim 1, wherein an outer or front face of the elongate housing (14) is defined by a transversely domed or convex segment.

7. A housing assembly according to any of the previous claims, wherein the mounting rails (30) have an integral leg or rib for elevating the rail from an edge or surface.

8. A housing assembly according to any of the previous claims, wherein the interior of the housing (14) is provided with support means (19a, 19b) for one or more webs or strips (9) extending longitudinally of the housing.

9. A strip lighting device comprising a housing assembly according to any of claims 1 to 8, further comprising light sources (8) disposed in the passageway of the housing.

10. A strip lighting device according to claim 9 wherein said light sources (8) are semiconductor devices or light emitting diode devices.

11. A strip lighting device according to claim 10 wherein said semiconductor or light emitting diode devices are arranged on a printed circuit board strip (9) extending along and mounted within said passageway.

12. A strip lighting device according to any of claims 9 to 11, wherein a further strip or web is provided which is an optical refractor or diffuser, and which is arranged in front of or behind the light sources (8).

13. A strip lighting device according to any of claims 9 to 12, further including connector means (100, 110) to physically couple said elongate housing (14) to a similar housing of a further device whereby the housings may be relatively longitudinally displaced in situ by thermal expansion or building subsidence, without being uncoupled.

14. A strip lighting device according to claim 13 wherein said connector means (100) includes an integral moulded body which defines a pair of generally tubular portions (102, 103) slidably engageable with the respective said housings (14) so that their interiors are in communication within the connector (100), wherein said integral moulded body further defines a relatively thin wall portion (104) between said generally tubular portions (102, 103), said thin wall portion (104) being resiliently deformable to compensate for relative variations in the relative positions of the generally tubular portions (102, 103).

15. A strip lighting device according to claim 13 further including means (110) to electrically and physically interconnect a circuit board strip (9) to a similar circuit board strip (9) of a similar device to which said device is coupled.

Drawing