GB2092734A - Lanterns for Area Lighting - Google Patents

Abstract

A lantern for an area light includes a transparent or translucent bowl (16) whose exterior includes a substantially central area having, in alternation, regions acting as reflecting prisms (5) and regions (7) substantially perpendicular to the vertical axis of the lantern. <IMAGE>

Description

SPECIFICATION Improvements In or Relating To Lanterns for Area Lighting The present invention relates to lanterns for area lighting and in particular for street lighting. It is the practice to light streets and other roadways with lights, now generally discharge lamps, mounted in part transparent or translucent housings, called lanterns, on suitable columns or other supports above a street to be illuminated. It will be appreciated that although this form of lighting is more commonly seen in streets it may be used in other circumstances perhaps to illuminate private premises both inside and out and for that reason it is generally described here as area lighting. All references herein to street lighting are to be taken to be applicable as appropriate to mther forms of area lighting.Area lighting for streets is generally subject to strict regulations regarding, among other things, intensity and distribution of light. This results from the application, which is to illuminate the road surface as economically as possible. A road user at night sees objects on the road in silhouette against a bright road surface. To provide such illumination a road lantern is generally designed to project light up and down a road, towards and away from an observer. That light which is directed towards an observer produces glare because the observer's eyes see not only light reflected off the road but also direct light from the lantern. The direction and intensity of the light from a road lantern determines the glare and also the required spacing of lanterns for uniform lighting.

A typical specification for road lighting lanterns is BS.4533 Part 2 of which section 2.7 classifies group A lantern photometric performance into two categories. One category (cut-off distribution) provides better glare control and a lower beam in elevation than the other (semi-cut-off distribution). The cut-off distribution allows the beams to extend to an elevation of 650 with an intensity at 900 in elevation (in the vertical plane parallel to the street axis) of 1 Scd/klm. The semicut-off allows the beam to extend to an elevation of 750 and the intensity at 900 in elevation to be 75 cd/klm. This intensity limit at 900 in elevation is an approximate measure of glare and, it can be seen, may be five times higher in semi-cut-off than in cut-off lanterns.In general it is 30% more expensive to illuminate a road with cut-off lanterns compared with semi-cut-off, since the cut-off distribution, having a lower beam angle, requires closer spacing for acceptable lighting uniformity.

A further requirement which applies to both distributions is that the maximum intensity within the cone from the downward vertical to an elevation of 300 should not exceed 80% of the peak intensity (or of the maximum within the beam). It is with compliance with this requirement that this invention is concerned.

It has been the practice to obtain the appropriate distributions by the choice of lantern design. A lantern generally includes two parts, a transparent or translucent bowl facing the surface to be illuminated, and an opaque canopy above, with the discharge tube or tubes mounted therein.

The lantern may include reflectors and the bowl may include shaped surfaces to refract the light.

In general a cut-off distribution is obtained from a lantern including reflectors. In such an optical design, light is reflected off reflectors on both sides of the lamp to pass underneath and around the end of the lamp. This requires a relatively large lantern, to include the reflectors, compared with a refractor type of optical design in which light is emitted from the lantern through prism bands on either side of the lamp integral with the lantern bowl. However, since in general refractor optics produce more glare than reflector control, it has been usual to reserve refractor optics for semi-cut-off distributions.

It is an object of this invention to provide an improved optical design for area lighting lanterns for the control of intensity directed vertically downwards from the lamp, substantially within a 300 Cone. This is particularly useful for a cut-off distribution but is also applicable to semi-cut-off.

According to the invention there is provided a lantern, for an area light, including a transparent or translucent bowl whose exterior includes a substantially central area having, in alternation, regions acting as reflecting prisms to light passing therethrough and regions substantially perpendicular to the vertical axis of the lantern.

In order that the invention may be clearly understood and readily carried with effect it will now be described by way of example with reference to the accompanying drawings, if which: Figure 1 shows the central region of the bowl of a prior art lantern, Figure 2 shows the same region of a lantern in accordance with the invention, Figure 3 shows an alternative form of the prisms 5 of Figure 2 and, Figure 4 shows a complete lantern in accordance with the invention.

The description of the invention will be in relation to a new design of lantern providing cutoff distribution by purely refractive optical design.

It should be noted, however, that the optical design for control of the vertical light intensity is applicable both to cut-off designs using reflectors and semi-cut-off designs.

In general such lanterns are mounted to illuminate a surface directly there below. However the lanterns may be mounted in other positions.

In this specification the words vertical and horizontal are considered to have that relationship to the lantern, however it is mounted, which they would have when the lamp is mounted conventionally above level ground with the vertical axis perpendicular to the illuminated surface.

Considering an existing arrangement giving semi-cut-off distribution for a typical discharge lamp, a 135 Watt SOX (low pressure sodium) iamp, the lantern comprises a white glass reinforced plastic (GRP) canopy with a clear prismatic bowl below. The existing semi-cut-off version has a shallow canopy with a semi-circular cross-section of bowl. In comparison the cut-off development has a deeper canopy with a shallower bowl having a relatively flat prismatic base and clear and nearly vertical sides. Since refractor only optics are used the overall size is smaller than for conventional reflector designs, and has lower material costs.

The bowl is designed to be as shallow as possible to keep the projected area from the side in the horizontal direction to a minimum. This helps to reduce horizontal light intensity due to light scattered in the bowl material. In conjunction with this the bowl is expected to have sufficient flashed projected area (defined as an area projecting an image of the light source) in the direction of a peak, which should produce a minimum intensity of 200 cd/1 000 lamp lumens in a region between 600 and 650 from the downward vertical.

As mentioned hereinbefore, an important requirement with which this invention is concerned is that of limiting the downward intensity to less than 80% of the peak intensity.

In achieving this requirement problems arise because of the flat and shallow nature of the bowl of which the projected area is significantly greater in the 0 to 300 region then when viewed from 650.

Figure 1 shows in cross-section perpendicular to the principal axis of the lamp, the centre part of the bowl of a prior art cut-off lantern. Over most of the bottom of the bowl there are formed internally facing prisms 1 which extend substantially from the complete length of the bowl. The light falling on such prisms becomes increasingly less effective when it strikes them from closer to the vertical axis 2. This axis, which is usually vertical in relation to the street surface, is in fact the central plane of symmetry of the lantern but will be called the vertical axis herein. As a result there is too much light in the downward direction compared with that in the direction of peak intensity.

To correct this to some extent, in a central region AA the prisms are replaced by semicircular grooves 3 which scatter rather than controlling the light from the lamp. The aim is then to scatter a sufficient amount of light out of the 0 to 300 cone. Some light paths 4, from the lamp, are shown to clarify the optics of the designs.

It is, however, found that this is still not as effective as would be desired and Figure 2 shows the same cross-section as Figure 1 but incorporating the improved optical design of this invention. Prisms 1 are provided as before but in the centre the inside grooves 3 have been replaced by prisms 5 on the outside of the bowl.

These prisms 5 are reflecting prisms since a light ray entering a prism will be internally reflected, as well as being refracted before leaving the prism.

This can be seen with a ray between limits 6 and 61, of which 4, is typical, which is reflected in prism Si as shown. In prisms 1 in contrast there is only refraction. Between each prism 5, including the terminating half prisms 5', there is a flat region 7. Some light, such as that of ray 42 passes straight through the flats 7, giving a vertical beam, while those, such as 43 and 44, passing through the prisms 5 are largely reflected out of the vertical beams.

The ratio of prisms 5 to fiats 7 in area may be varied to adjust the intensity of the vertical beam but the prisms 5 should be sufficiently closely spaced to give the appearance of a completely flashed prism bank in the direction of the main beam (that is, at the peak). It is preferred that 1/3 of the vertical light beam passes through flats 7.

An additional advantage resulting from the presence of the flats 7 is in ease of cleaning of the bowl exterior.

Certain considerations should preferably be met in the design of these prisms 5. TheexternaI surface 8 of the bowl is substantially flat but is in this example a shallow curve. If a chord to this curve is as shown at 9, across the prisms 5, it is preferred that the tops of the prisms do not protrude beyond this chord so as to reduce the risk of spill light being refracted out at 900. The inner surface 10 above prisms 5 is also preferred to be parallel to chord 9 or at least to not deviate from parallelism by more than about 5 . It may also be curved provided the maximum deviation from the side of the arc to the bottom does not exceed about 5 .

Although triangular prisms with intervening flats have been illustrated in Figure 2 it will be understood that the invention may be implemented, with some loss of performance, by shapes which approximate to that ideal. For example Figure 3 illustrates how the prisms may be approximated by grooves or flutes 11 with concavities outward facing. The top most parts of these tend to act as flats 7 while the regions of the cusps 12 tend to act as reflecting prisms.

Such grooves do, however, tend to scatter the light as opposed to controlling it and are not preferred.

Figure 4 shows in cross-section a complete cut-off lantern in accordance with the invention. A 135 watt SOX lamp 13 having a U-shaped discharge tube 14 is enclosed in the lantern which comprises a canopy 1 5 and bowl 1 6. The two are clipped together by conventional means (not shown) and sealed with a sealing pad 17 to exclude moisture. Other features are identified by the same reference numerals as in the earlier Figures. The lamp illustrated is 775 mm long 67 mm diameter. The length of the lantern (perpendicular to the Figure) is generally slightly longer than the tube in use. All dimensions clearly may vary with the application and powers of the lamp. It is preferred that the prisms 5 extend for substantially the full length of the lantern.They may, however, merely extend only over a sufficient region to achieve the desired 80% intensity. The remainder of the central region may be provided with internal grooves 3 as shown in Figure 1.

Although the ratio of the width WA of the exterior prism region to the width WB of tha total lantern, should be adjusted for best results it is in practice a ratio which varies for different designs and lamps. In general it should be adjusted so that the prisms 5 have a sufficient interception of the 0--300 beam but varies with the application.

The invention has been described in terms of a lantern for a low pressure sodium light having a linear tube to which the external reflecting prism are parallel. It will be appreciated that it is applicable to other forms of lamp. For example mercury lamps and some high pressure sodium (SON) lamps generally have elliptical outer envelopes. These are often used with more rounded shapes of bowl. In application of this invention that bowl shape could be used with the external reflecting prisms in curved disposition generally concentric around the lamp. Other shapes can be devised to suit other lamp configurations.

Claims (Filed 13/1/82) 1. A lantern, for an area light, including a transparent or translucent bowl whose exterior includes a substantially central area having, in alternation, regions acting as reflecting prisms to light passing therethrough and regions substantially perpendicular to the vertical axis of the lantern.

2. A lantern according to claim 1 in which the regions acting as reflecting prisms are sufficiently closely spaced to provide a completely flashed prism bank when viewed from the direction of peak intensity of the lamp.

3. A lantern according to claim 2 in which the said direction is between 600 and 650 from the said vertical axis.

4. A lantern according to any of the preceding claims in which the regions acting as reflecting prisms are sufficiently spaced to allow at least one third of light travelling substantially parallel to the vertical axis to pass through said perpendicular regions.

5. A lantern according to any preceding claim in which the external surface of the bowl has a base part, including said central area, which is substantially flat outside said central area and in which the internal surface of the central area is substantially parallel to said flat part.

6. A lantern according to any of claims 1-4 in which the external surface of the bowl has a base part, including said central area, which is convex outside said central area.

7. A lantern according to claim 6 in which the tips of said regions acting as reflecting prisms do not protrude beyond a chord to said convex surface between the extremes of the central area.

8. A lantern according to claim 7 in which the inside surface of said central area does not deviate by more than 50 from parallelism to said chord.

9. A lantern according to any of the preceding claims in which the regions acting as reflecting prisms are substantially triangular prisms.

10. A lantern according to any of claims 1-8 in which the external surface of said central area is formed with outwardly facing concave flutes of which the cusps are substantially perpendicular to said vertical axis.

11. A lantern according to any preceding claim in which said regions acting as reflecting prisms are linear and disposed substantially parallel to each other.

12. A lantern according to any of claims 1-10 in which said regions acting as reflecting prisms are curved and disposed around the centre of said central area.

13. A lantern, for an area light, including a transparent or translucent bowl whose exterior includes a substantially central area having, in alternation, substantially flat regions and regions protruding from the bowl to function as reflecting prisms.

14. A lantern, for an area light, substantially as herein described with reference to Figures 2 to 4 of the accompanying drawings.

1 5. An area having a lantern according to any of the preceding claims.

1 6. An area light according to claim 1 5 arranged to have a cut-off light distribution.

**WARNING** end of DESC field may overlap start of CLMS **.

Claims (14)

**WARNING** start of CLMS field may overlap end of DESC **. sufficient region to achieve the desired 80% intensity. The remainder of the central region may be provided with internal grooves 3 as shown in Figure 1. Although the ratio of the width WA of the exterior prism region to the width WB of tha total lantern, should be adjusted for best results it is in practice a ratio which varies for different designs and lamps. In general it should be adjusted so that the prisms 5 have a sufficient interception of the 0--300 beam but varies with the application. The invention has been described in terms of a lantern for a low pressure sodium light having a linear tube to which the external reflecting prism are parallel. It will be appreciated that it is applicable to other forms of lamp. For example mercury lamps and some high pressure sodium (SON) lamps generally have elliptical outer envelopes. These are often used with more rounded shapes of bowl. In application of this invention that bowl shape could be used with the external reflecting prisms in curved disposition generally concentric around the lamp. Other shapes can be devised to suit other lamp configurations. Claims (Filed 13/1/82)

1. A lantern, for an area light, including a transparent or translucent bowl whose exterior includes a substantially central area having, in alternation, regions acting as reflecting prisms to light passing therethrough and regions substantially perpendicular to the vertical axis of the lantern.

2. A lantern according to claim 1 in which the regions acting as reflecting prisms are sufficiently closely spaced to provide a completely flashed prism bank when viewed from the direction of peak intensity of the lamp.

3. A lantern according to claim 2 in which the said direction is between 600 and 650 from the said vertical axis.

4. A lantern according to any of the preceding claims in which the regions acting as reflecting prisms are sufficiently spaced to allow at least one third of light travelling substantially parallel to the vertical axis to pass through said perpendicular regions.

5. A lantern according to any preceding claim in which the external surface of the bowl has a base part, including said central area, which is substantially flat outside said central area and in which the internal surface of the central area is substantially parallel to said flat part.

6. A lantern according to any of claims 1-4 in which the external surface of the bowl has a base part, including said central area, which is convex outside said central area.

7. A lantern according to claim 6 in which the tips of said regions acting as reflecting prisms do not protrude beyond a chord to said convex surface between the extremes of the central area.

8. A lantern according to claim 7 in which the inside surface of said central area does not deviate by more than 50 from parallelism to said chord.

9. A lantern according to any of the preceding claims in which the regions acting as reflecting prisms are substantially triangular prisms.

10. A lantern according to any of claims 1-8 in which the external surface of said central area is formed with outwardly facing concave flutes of which the cusps are substantially perpendicular to said vertical axis.

11. A lantern according to any preceding claim in which said regions acting as reflecting prisms are linear and disposed substantially parallel to each other.

12. A lantern according to any of claims 1-10 in which said regions acting as reflecting prisms are curved and disposed around the centre of said central area.

13. A lantern, for an area light, including a transparent or translucent bowl whose exterior includes a substantially central area having, in alternation, substantially flat regions and regions protruding from the bowl to function as reflecting prisms.

14. A lantern, for an area light, substantially as herein described with reference to Figures 2 to 4 of the accompanying drawings.

1 5. An area having a lantern according to any of the preceding claims.

1 6. An area light according to claim 1 5 arranged to have a cut-off light distribution.