Light Source for a Luminaire

Abstract

The object of the present invention is to provide a light source (101) for a luminaire or lantern, the light source (101) comprising: at least one light emitting diode (LED), a mantle structure (112) with which the LED (101) is fast within the mantle structure (112), the mantle structure (112) being both transparent or at least translucent and arranged to intercept and re-distribute light from the LED and, an optical element (117) in the mantle structure (112) for biasing light from the LED (101) away from a direction in which illumination is unwanted or at least is wanted at reduced intensity. The optical element (117) is angularly adjustable such that the light emitted may be directed.

Claims

1-16. (canceled)

17. A light source for a luminaire or lantern, the light source comprising: at least one light emitting diode (LED), a mantle structure with which the at least one LED is fast within the mantle structure, the mantle structure being apertured to assist further light redistribution, and: transparent or at least translucent, arranged to intercept and re-distribute light from the LED, and a collar comprising at least a pair of spring detents, at least one optical element in the mantle structure for biasing light from the LED away from a direction in which illumination is unwanted or at least is wanted at reduced intensity, and an LED base upon which the mantle structure is fast, the base having a circularly arranged set of depressions for reciprocal communication with the spring detents, whereby the mantle structure is an angularly adjustable support for the optical element.

18. A light source for a luminaire or lantern according to claim 17, wherein the optical element is angularly adjustable.

19. A light source for a luminaire or lantern according to claim 17, wherein the optical element is any one of: a reflector, a prismatic device, or a light shield.

20. A light source for a luminaire or lantern according to claim 17, wherein there is provided a central screw fixing the optical element within the mantle.

21. A light source for a luminaire or lantern according to claim 17, wherein the optical element is configurable to: reduce light intensity in one direction, disperse light generally through other directions, or concentrate light in one or more specific directions.

22. A light source for a luminaire or lantern according to claim 17, wherein more than one optical element and/or light source is provided per luminaire.

23. A light source for a luminaire or lantern according to claim 17, wherein the optical element for directing sideways light is generally parabolic.

24. A light source for a luminaire or lantern according to claim 17, wherein the angularly adjustable support and/or mantle are adjustable arranged on to a heatsink or base therefor, upon which the LED(s) and its/their PCB are carried.

25. A light source for a luminaire or lantern according to claim 24, wherein respective heat sinks are provided for the light sources where there is more than one light source.

26. A light source for a luminaire or lantern according to claim 24, wherein the support is clipped onto the heatsink base and provided with sprung detents for preserving the adjustment.

27. A light source for a luminaire or lantern according to claim 17, wherein the mantle structure is mounted in use to extend down or up from the support.

28. A light source for a luminaire or lantern according to claim 17, wherein the LED has a phosphor coating and/or a lens for focusing the light in a particular direction.

29. A light source for a luminaire or lantern according to claim 17, wherein the optical element is arranged at the bottom of the mantle structure to spread downwards light to reduce intensity of illumination immediately below the light source, and/or the or another reflector can be arranged to one side of the mantle structure to reduce sideways or other direction of illumination.

30. A light source for a luminaire or lantern according to claim 17, wherein the mantle is generally paraboloid in shape.

31. A light source for a luminaire or lantern according to claim 17, wherein the optical element is polymeric with a reflective coating, or metallic.

Description

[0032] To help understanding of the invention, a specific embodiment and a variant thereof will now be described by way of example and with reference to the accompanying drawings, in which:

[0033] FIG. 1 is a perspective view from above of a developed light source;

[0034] FIG. 2 is a side view of the light source of FIG. 1;

[0035] FIG. 3 is a view similar to FIG. 1 of the light source from below (but on its side);

[0036] FIG. 4 is the same view as FIG. 3 with the mantle removed from the light source;

[0037] FIG. 5 is a side view of a luminaire with light sources of FIG. 1;

[0038] FIG. 6 is a perspective view from below of the luminaire of FIG. 5, with a lower cover removed; and

[0039] FIG. 7 is a cross-section view of the luminaire of FIG. 6 based on a similar perspective view.

[0040] Referring to the drawings, the embodiment there shown is of the new development beyond Our Earlier Application.

[0041] Referring to FIGS. 1 to 4, the light source 101 has an LED chip unit 102 mounted centrally on a PCB 103. This is held fast onto an LED base 104 by screws 105 passing through the base to a heat dissipater or heat sink 106. The latter has a plurality of pins 107 to increase its surface area and allow heat transfer to surrounding air. The screws engage in a disc 108 of the heat sink, from which disc the pins extend, and they draw the PCB into heat conducting with the LED base.

[0042] A details is that the PCB, base and disc are bored for a power supply cable, not shown, to the PCB for illuminating the LEDs.

[0043] The base has a rim 109 around the PCB in which a circular array of depressions 110 are milled. A 3D printed mantle 112 has an integral collar 114 with a series of lips 115 arranged to over-hang the rim 109. Thus they hold the mantle to the LED base. The collar has a pair spring detent 116 set in it. The mantle has a reflector 117 set in it.

[0044] The detents and the depressions allow the clipped one mantle to be turned around the base to orient the reflector in a desired direction.

[0045] As shown, the reflector has length along which it is concavely curved towards the LEDs. It also has a cusp in cross-section transverse to its length whereby it reflects and spreads light incident on it in a sideways direction away from the reflector. The reflector does not have as strong a directional effect as if it were a parabolic reflector or indeed a circular section one, both of which are envisaged to be possible variants. Rather it spreads light incident on it to give broadly directional illumination. It also shields the region behind it which could otherwise but unwantedly illuminated by the LEDs.

[0046] The reflector can be made of polymeric material, suitably metallised to be reflective. Alternatively it can be metallic

[0047] Turning now to FIGS. 5 to 7, a luminaire 201 for a lamp standard (not shown) has a fixture ring 202 with a hinge 203, via which an upper, opaque cover 204 and a lower transparent cover 205 are hinged to the fixture ring. Remote from the hinge, closure formations are provided, in particular for supporting the transparent cover which extends down from the fixture ring in use.

[0048] The fixture ring has an integral plate 206, above which power supply circuitry 207, which is essentially conventional, is supported on a plate 208. Below the plate 206 a circle of inter-engaging spacers 208 is fastened. They carry a lower plate 209 to which a clamping plate 210 is fastened by a central bolt 211. Both plates have respective circular cut-outs 212,214. The lower plate cut-outs are sized to receive the LED bases 104 of a plurality of light sources 101, with their heat sink discs 108 resting on the lower plate. The clamp plate cut-outs receive the heat sink pins 107 of each light source. With the bolt 211 tightened, the light sources are held fast. Their bases have nicks 118 and the lower plate has tabs 215. These inter-engage, where the LED bases are oriented in a pre-set direction. Angular graduations 216 are provided around each at each cut-out 212. Thus the mantles can be rotated to predetermined angles on assembly. Final adjustment of the angle of the mantles and their reflectors can be made after installation, with lower cover open.

[0049] The invention is not intended to be restricted to the details of the above described embodiment. For instance, where the appearance of a gas mantle is not required, the mantle can be formed with fewer strands than shown giving a more open appearance, with less secondary emission from them. Indeed it may be continuous and transparent. Further it may be shaped merely as a support around the edge of the reflector, with the support still being integral with the adjustment collar.

[0050] The reflector can be more extensive than shown, in particularly angularly. It can also be augmented by a further reflector across the inside of the distal end of the mantle to mitigate light pooling.

[0051] It is also envisaged that the reflector may be integrated into the mantle, as with prismatic elements extending around part of the mantle in the manner of a Fresnel lens. Alternatively, the mantle or a vestigial part of it, may be 3D printed and then metallised.