This invention relates in general to electric lighting and more particularly to lighting that uses different colors to indicate, for example, the nature, status, position, orientation, etc., of the object bearing the lighting.
Differently colored lights have been used as indicators for a very long time. Sometimes, colors indicate absolute or relative position, such as that a viewer is in a “dangerous” as opposed to a “safe” sector. Every nighttime driver knows the difference between red tail lights and white headlights.
As another example, in 1848 the United Kingdom began requiring certain ships to display red and green navigation sidelights on their port and starboard sides, respectively; this rule was adopted internationally in 1898. Nowadays, the International Regulations for Preventing Collisions at Sea 1972 (COLREGS) published by the International Maritime Organization (IMO) specify which lights of which colors may/must be displayed by vessels of different types, lengths, etc. For most categories, for example, a vessel underway from sunset to sunrise must display a red sidelight whose light is visible from straight ahead (0°) to 22.5° abaft the starboard beam, that is, 112.5° arc, a green sidelight visible from 0° to 22.5° abaft the port beam, and a white stern light visible over the remaining 135° arc centered on the stern.
As for visibility, COLREGS, Part C (“Lights and Shapes”), Rule 22 (“Visibility of Lights”) (b), specifies, for example, the following minimum visibility ranges for navigational lights for vessels of 12 meters or more in length but less than 50 meters in length:
a masthead light, 5 nautical miles (nm), except that where the length of the vessel is less than 20 meters, 3 nm;
a sidelight, 2 nm;
a sternlight, 2 nm; a towing light, 2 nm;
a white, red, green or yellow all-round light, 2 nm.
For the sake of compactness, wiring simplicity, etc., especially smaller vessels often use lights that combine two or more colors in a single fixture. For example, a single red/green light can be mounted on the centerline at the bow of the boat, or a sailboat less than 20 m in length may have a tri-color light at the top of the mast.
In known lights of the type shown in
Of course, the translucent lens member 40 may be divided into more than two portions, and different colors may be used besides red and green. In a masthead tri-color light, for example, the translucent lens will extend essentially 360°, with a clear portion 40W (
As mentioned, each colored portion 40R, 400 of the translucent lens 40 acts as a filter to pass the respective intended color (that is, range of wavelength) of light from the source 50. This makes it possible to use a single light source 50 (one or maybe even more bulbs or other light-emitting elements) yet still have light of different desired colors from a single light, but it also carries a clear disadvantage: To filter out unwanted wavelengths also means to reduce the intensity of the light that otherwise would pass through the translucent lens 40.
As a result, given known lights of the type illustrated in
What is needed is a light that reduces or eliminates some or all of the shortcomings of existing multi-color indicator lighting.
Various aspects of the invention are described below primarily using the example of a multi-color light suitable for use in a maritime environment, such that the example could be used to replace and improve upon the lights shown in
One advantage of using this environment as an example is that it is particularly demanding. Nonetheless, marine lighting is only one area in which the different aspects of the invention will be useful—as both users and skilled lighting designers will appreciate, the improvements provided by this invention may be applied to other situations as well in which it is desired to have efficient multi-color indicator lighting.
The dies 501, 502 will typically be mounted on a metallic base 510 held by a non-conductive supporting member 520. As the figure shows, the dies 501, 502 may be electrically connected with each other and a typically aluminum PCB 540 by conductors 511, 512, 513 and conductive vias or electrodes 530, 531. The PCB 540 may also be mounted on a heat sink 550. A lens 560 is mounted over the various LED dies 501, 502. Other components will usually also be included in a multi-die LED package such as package 500, but are not shown in the figures for the sake of simplicity and clarity—LED designers know what other parts will be needed. The main point to be illustrated in
Common electrodes (for example, “legs” 620, 622, portions of a screw-in or bayonet fitting, etc.) may lead electrical current to and from the entire set of dies 611. The lens 560 (
As is indicated by the different “R” and “G” arrows, the LED device 600 will radiate two (in this example) different primary light colors (wavelengths) simultaneously from the common package, since the different dies will be energized commonly. This “combined” light will then pass to both the green and red portions 40G, 40R of the lens, where the green lens portion 40G will pass most (minus absorption and reflection) of the green light but block most of the red light; similarly, the red lens portion 40R will pass most of the red light but block the green.
In other words, no structure is required to separate or isolate the different wavelengths at the source. Since the different LED elements (the dies) are in a common package, there is no need for complicated individual mounting and alignment and soldering of individual LEDs, no need for separate reflectors (a particular advantage where small overall size is important) for different colors, etc.
Note that one advantage of using LEDs is that they can be fabricated to radiate light in a much narrower wavelength band than an incandescent or fluorescent bulb, so that more of the applied electrical energy is converted into light that can actually be transmitted through the lens 40. In other words, not only are LEDs more electrically efficient in general (much less heat loss, etc.) as is known in the art, but they also are more efficient in that they cause much less waste of energy by radiating since they radiate more light of desired wavelengths. Another advantage of LEDs is that they are usually much more compact than other technologies, such that more light-radiating devices can be fit in the same space as a bulb. Compactness and efficiency are improved even further if the different light-generating elements are formed as different dies in a common package as illustrated in
In the case of the tricolor indicator light with red, green, and clear (that is, “white” or non-colored) lens portions, the LED package 600 would contain at least one red die, one green die, and a “white” LED. Note that a “white” LED typically is fabricated using a blue LED die with a specific phosphorus compound; in other words, a “white” LED typically radiates a combination of “blue” and “yellow.” The LED device 600 will then radiate red, green, blue, and yellow light colors (wavelengths) simultaneously from the common package, since the different dies may be energized commonly. (Note that the spectrum for yellow LED light will typically be much broader than for red or green.) This “combined” light will then pass the green, red, and clear portions of the lens. The green lens portion 400 will pass most (minus absorption and reflection) of the green light but block most of the other light; similarly, the red lens portion 40R will pass most of the red light but block other colors of light, and the clear lens portion 40W will pass most of the “white” light as perceived by human eyes.
Note that it will not matter if red and green light also passes through the clear lens portion 40W: Since LED “white” is typically a combination of blue and yellow spectral regions, the addition of red and green to the spectrum will actually make the light appear more “white” to the human eye. Similarly, the inclusion of red and green LEDs along with the white LEDs would make the combined light appear more white to the human eye.
According to another aspect of an embodiment, the light includes a common reflector 710. The surface 720 of the reflector 710 is preferably as reflective as possible, but this will depend on how much cost and manufacturing effort one wishes to devote to this. The reflector 710 may be annular, but may also have some other shape depending on the shape of the overall light casing, the desired light pattern, etc. The reflector need also not be purely conical, that is, with a “straight line” surface from base to tip, but may instead be given whatever curvature is desired to reflect incident light in a desired pattern. It would also be possible to truncate the tip of the reflector if this would have some advantage in a given implementation.
As
Second, the surface 720 of the reflector 710 can be made such as to improve the ability to keep the transmitted light in a required or desired elevational range. For example, in maritime uses, there is little point directing navigational light over a broad range of elevation: Very few observers will ever be more than about 25 meters above the sea surface, so beyond 100 meters most light aimed more than about 15° up will be wasted energy, as will light directed at the seas surface close to the vessel. Thus, for marine navigation lights, most light should be directed in a narrow elevational range “aimed” about ±25° with respect to the horizon. Normal design and geometrical methods may be used to calculate or otherwise determine the appropriate surface geometry of the reflector. Of course, other environments than the maritime will have other requirements, and the reflector 710 surface 720 may then be chosen accordingly. An additional, secondary optical lens may also be used to improve the performance of the light in the radial or other directions in conjunction with the reflector 710, or independently.
As mentioned above, more than two colors may be included in the common LED package, and the invention may be used even when the desired colors are other than red or green. In a tri-color masthead light, for example, dies for “white” LEDs may also be included in the common package along with red and green. As is known, “white” LEDs may in fact themselves be composites with spectrum peaks in the yellow and blue wavelength regions. The white light will then be emitted from the common device “mixed” with the green and red. The clear or at least non-colored rear lens portion 40W (see
In the prior art light shown in
As can be appreciated from
The vertical separation between the top of the common LED device 600 and the tip of the reflector 720 need not be as shown in
As an example of the improved efficiency provided by various aspects of the invention, one prototype of an embodiment similar to the one shown in
The invention may of course be included in original lights, but its compactness and efficiency also make it well-suited to replace bulbs with less efficient technologies (for example, incandescent) in existing light fittings. In other words, the various aspects of the invention can be used to make after-market, high-efficiency light bulb replacements.
In this case (red), the light-emitting member 50 should preferably be red to maximize intensity, but note that this is not strictly necessary: Even if a multi-color, multi-die LED member 50 is used, then the “undesired” colors will simply be either blocked by the film or not transmitted by the uncovered lens portion(s), whereas any “stray” light of the desired color will be directed in the useful direction.
Light that does not pass directly through the red lens portion 40R will therefore reflect laterally off of the reflective film 1010 and be ultimately directed towards the red lens portion 40R as well. The reflective film 1010 thus reduces “waste” of light energy.
The reflective member such as reflective film 1010 will typically be metallic and flexible, although this is not necessary—any material such as plastic that is highly reflective and can be formed to fit the inside or outside of the light housing will be suitable—if the chosen material is not flexible, then it should be shaped for insertion and mounting on the inside or outside of the translucent lens 40. Any mechanical or adhesive means may be used to secure the reflective film or member 1010.
Of course, if the light-emitting element 50 is red, then the lens portion 40R need not be red at all, but may be clear; in fact, in the illustrated embodiment, any or all of the lens members 40 may be clear, since only the desired color of light will be passed.
The principle shown in