Single LED and lens assembly

An apparatus and method for producing a light output pattern from a single LED source through a lens that diverges light at or around the center of the lens from a single source but converges light at concentric areas around the center area. The assembly can avoid a central hot spot of intensity in the light output pattern and create one or more concentric rings of higher apparent intensity.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a lighting assembly utilizing a single LED as the light source and a lens for modification of the output of the single LED. In particular, the invention relates to a light assembly that attenuates the appearance of intensity along the optical axis of the light source and accentuates the appearance of intensity at one or more surrounding areas of the center axis.

2. Problems in the Art

Many lighting assemblies or fixtures with a single light source result in a central “hot spot”; the appearance of much higher intensity in alignment with the light source, with progressively diminishing apparent intensity moving radially away from the light source. This is true even with transparent or translucent covers or lenses over the light source. While many applications function adequately for the intended lighting or illumination purpose in that configuration, it can be distracting. In some cases it can even represent a safety concern. Furthermore, it is aesthetically and visually displeasing in certain applications or to certain people.

Additionally there are circumstances where an apparent “hot spot” at the lens of a light assembly performs adequately, but conventional light sources, like incandescent sources, leave room for improvement with respect to such things as durability, effective operating life, and electrical power consumption.

An example is a tail light for an over-the-road semi-trailer pulled by a semi-trailer truck, otherwise known as a tractor or semi. Many times such a tail light is multi-functional, in the sense it performs several functions, e.g., brake light function, turn signal function, and running light function. For simplicity and cost purposes, many conventional semi-trailer tail lights combine all three functions in a single light assembly. They commonly are four inch round diameter devices including a cup-shaped base holding a single incandescent lamp covered with a red transparent or translucent lens. The running light function involves illuminating the incandescent lamp at a first intensity. Well known circuitry increases the intensity to the incandescent lamp if the truck's brakes are operated. Intensity is varied if the turn signal is operated.

There are well known regulations (e.g. DOT/SAE) regarding the light output for such multi-function lights, including the light pattern and its intensity. The relatively low cost of incandescent sources has resulted in lights of this type essentially comprising a relatively high-powered incandescent lamp, an economical base, and a simple, minimal complexity cover or lens. DOT/SAE regulations generally specify just minimum intensity requirements at a certain distance away from the light. Therefore, the state-of-the-art generally takes the approach of generating well over the needed intensity with the relatively cheap incandescent source and directing it through minimal optics, all with the hope of flooding the target space of the regulations sufficiently to meet the minimums.

However, room for improvement with regard to this type of light has been identified. The above-described combination basically results in a “hot spot” of intensity right at the center of the tail light, with diminishing intensity as you move out from the lens center. If the brake or turn signal function is operated, it accentuates the hot spot. It can be distracting, and even dangerous, for someone following a large vehicle. It can create discomfort or even disability glare that could impair safety of the driver in the vehicle following.

There is a real need in the art, therefore, for a tail light light that meets minimum intensity requirements for such a light but without the “hot spot”.

The mere fact the hot spot is visually distracting, and to some unappealing, is a problem in the art. There is therefore a real need in the art for a tail light of this type that does not have a central hot spot.

Incandescent light sources, although relatively cheap, have many weaknesses. They utilize glass envelopes and thin metal filaments. They are susceptible to vibration and shock. They also have inconsistent and relatively limited expected operating life relative to other light sources such as light emitting diodes (LEDs). They also tend to be relatively inefficient with respect to electrical power consumption.

It is well known that LEDs have substantial anticipated operating life (thousands of hours) and typically outlast incandescent sources by substantial amounts. They are also shock resistant and power efficient compared to incandescent lights. Attempts have been made to use LEDs in tail lights. However, they are significantly more expensive than incandescent sources, and conventional LEDs do not have as high of light output. Therefore typical LED attempts have used a plurality (four or more) LEDs. This multiplies the cost because the LEDs represent a significant amount of overall cost of such fixtures. Tail lights each having multiple LEDs have become increasingly accepted but are considered a premium or high cost product.

There is therefore a real need in the art for an improvement regarding this type of light.

Analogous issues exist for other lights. This includes other automotive-type lights or other light applications outside of automotive uses. Interior lighting is but one example.

BRIEF SUMMARY OF THE INVENTION

It is therefore the principle object, feature, advantage or aspect of the present invention to provide an apparatus and method which solves or overcomes problems and deficiencies in the art.

Other objects, features, advantages or aspects of the present invention include an apparatus and method as above described which:

a. utilizes a single LED source as the light source;

b. if applicable, meets government or other regulations for output pattern and intensity;

d. is durable and robust;

e. is power efficient;

f. is relatively economical; and

h. takes away a central perceived “hot spot” from the light.

According to one aspect of the present invention, a tail light apparatus includes a single LED light source and a lens. Specific regions of a lens are directed to pre-determined specific regions of an output pattern from the light. In one example, radially outward lens surfaces direct light to the center of the pattern. More central lens surfaces direct relatively less light to the center of the pattern. This results in brighter areas at the outward portions and lower apparent intensity at the central portion. This presents a distinctive appearance and reduces a single central “hot spot” that can cause glare.

In another aspect of the invention, a method of producing a light output pattern from a single LED source is provided. The output pattern has a center and a perimeter and is generated through a lens which is substantially larger than the single light source but avoids a high intensity appearance or “hot spot” at the center—i.e. along an axis between the source and the center of the output pattern. The method includes adapting a lens area to direct a relatively smaller amount of light from the source to and around the center of the output pattern; while at the same time adapting other areas of the lens to direct relatively larger amounts of light to the center of the output pattern. This attenuates perceived intensity at the traditional center “hot spot” of the light while maintaining light output requirements of the pattern. Manipulation of light from the single LED light source in this manner allows a unique appearance when operating, while meeting light output intensity requirements and diminishing or eliminating a single “hot spot”.

According to another aspect of the present invention, an apparatus includes a base with an opening, a single LED source operatively mounted in the base, and a cover over the opening. The cover comprises a first lens portion directing a relatively small amount of light from the source to the center of an output pattern and a second lens portion directing a relatively large amount of light from the source to the center of the output pattern.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENT

Overview

For better understanding of the invention, one example of a form the invention can take will now be described in detail. Frequent reference will be taken to the drawings, described above, and reference numbers and/or letters will be used to indicate certain parts or locations in the drawings. The same reference numbers and letters will be used to indicate the same parts and locations throughout the drawings unless otherwise indicated.

This exemplary embodiment will be described in the context of a red, four inch diameter round, stop-tail-turn light, according to DOT/SAE regulations, for vehicles including over-the-road semi-trailers. Specifically, the DOT/SAE regulation is SAE Surface Vehicle Standard J2040 (March 2000 Revision) for Tail Lamps (Rear Position Lamps) for Use on Vehicles 2032 mm or more in Overall Width. The standard is available from The Engineering Society For Advanced Mobility Land Sea Air and Space International, 200 Commonwealth Dr., Warrendale, Pa. 15096-0001, and is incorporated by reference herein in its entirety. The lighting assembly is a single cavity, single LED source fixture that is operable from a standard over-the-road truck electrical system. It is to be understood that this invention is not limited by this example and can take many forms and embodiments with variations from this exemplary embodiment.

Apparatus

FIG. 1illustrates the basic components of the tail light110according to the exemplary embodiment. A base112has a single cavity in which a single LED source130is operatively mounted according to means or methods within the skill of those skilled in the art. For purposes of discussion, an axis118will be referred to as the optical or center axis of tail light110. LED130is mounted substantially in alignment with axis118, which also is generally the central longitudinal axis of tail light110and passes through the center of a covering lens140that attaches over the opening to the cavity of base112.

FIG. 2shows tail light110in assembled form. As an assembly, it is configured to fit into industry standard openings and structure on the back of a conventional over-the-road semi-trailer12(seeFIG. 3).

FIG. 3diagrammatically illustrates such a trailer12. Two tail lights110L and R are installed at opposite lateral sides of a cross member or bumper116. Each is operatively connected to the wiring harness for a trailer12and will operate according to instructions based on turning the running lights on for the truck, operating the brakes, and/or operating the tail or turn light for either side.

Tail lights110are approximately four inch diameter red lens, grommet mount, lights. Therefore, when not on, they look similar to conventional four inch diameter red lens, grommet mount, state-of-the-art tail lights, whether those that utilize a single incandescent source or multiple LED sources.

With reference toFIGS. 1-5, base112of tail light110is basically a molded, plastic, cup-shaped member having a generally cylindrical side wall122, a closed back124, an open front126, and a flange or lip128around the open front126. It can be made economically through conventional manufacturing techniques and essentially defines an enclosure or cavity. A conventional mounting board and/or a heat sink (not shown) can mount within base112. A relatively high-powered red LED130(e.g. Luxeon model # LXH-LMH1D (Lambertian beam pattern), 1 watt red single LED (from Lumileds Lighting U.S. L.L.C., San Jose, Calif., USA), preferably forward voltage S Bin rating or higher) has a light emitting portion132extending along axis118and is mounted to mounting member/circuit board134which is mounted to base112or to another board and/or heat sink in base112by screws136. Circuit board134has electrical contacts (not shown). Wiring extends between the electrical contacts of LED mount/circuit board134and an internal plug (not shown). A grommeted wiring plug138, with associated power wires, can releaseably plug into base112. These features are conventional in the art.

Lens140is generally circular with a generally cylindrical side wall142. As can be seen inFIG. 5, side wall142has an outer annular edge144. The combination allows lens140to be matingly fit over the front edge126of base112and sit on flange128. Lens140can be secured in place by adhesives, snap fit, interference fit, threaded connection, or other methods. One example would be a sonic weld or seal as lens140is made of polycarbonate, as is housing or base112.

As is illustrated inFIGS. 1 and 2, and shown in more detail inFIG. 5, lens140has a relatively smooth outer or exit surface170, but a shaped inner surface150(seeFIG. 5). Shaped inner surface150basically uses a combination of refraction and/or internal reflection to control not only the output pattern of tail light110when light source130is on, but also the intensity distribution of the light110.

Around axis118at lens140is a central portion152(seeFIG. 5). It is slightly convex on inside surface150. A first raised facet154surrounds central portion152, and is generally circular and centered on axis118. Facet154has a sheer inward side and a long sloping outward side.

A second facet156surrounds first facet154and is smaller but of similar shape. This is followed by a still smaller third facet158.

Thereafter there are nine concentric facets having sheer inward sides and relatively steep opposite or outward sides. Each facet is essentially as big or bigger than a preceding facet. Reference numbers160-168refer to those nine facets.

FIG. 5shows, in isolation, a cross section of the specific profiles or topographies of the relatively smooth outer surface170of lens140and the multi-faceted inner surface52of lens140.FIG. 5also shows that profile relative to where LED130and its circuit board134would be positioned when assembled into base112.

FIG. 6illustrates data points that define surface150and its profile as follows. The X and Y values for each data point1-95refer to distances, in inches, relative the X and Y axes of shown inFIG. 5. The X axis is in the plane defined by the top of the circuit board134of LED130when that combination is assembled into tail light10. The Y axis is orthogonal to the X axis and extends up through essentially the center of lens40(and thus, is essentially co-axial with optical axis118). Thus, as illustrated inFIG. 5, data point1would define the bottom surface150of lens140at 0.1159 inch along and to the right of axis Y and 0.8776 inch up from and perpendicular to axis X. Data point2would define bottom surface150a slight distance more to the right along axis X, and so on until point95, which is radially close to 2 inches away from central axis118(or the Y axis).

The data points ofFIG. 6would define the topography, so to speak, of the inner side150of lens140along a radius from the central axis118radially outward towards the perimeter edge of lens140. This same topography would be revolved 360 degrees around central axis118to create the entire surface150. For example, a tool can be made that is complementary to the topography defined by the data points ofFIG. 6. A lens blank can then be turned, or the tool turned relative the lens blank, to revolve the lens blank relative the tool to create the 360 degree lens surface150. Some straight line approximation may be used to make the tool, but the data points ofFIG. 6should be close enough together that they are sufficient to define, to within reasonable limits of optical accuracy for this application, the surface150ofFIG. 5.

Operation

When light source130is on, it generates an output pattern basically conical or hemispherical in shape centered around axis118. Light incident on center portion152, and the areas comprising facets154,156,158, is substantially refracted away from axis118.

Conversely, light incident on facets160-168is substantially refracted, and internally reflected and refracted, towards axis118.

As a result, lens140functions to essentially direct a relatively small amount of light from single source130towards the center of the output pattern from fixture110, whereas it directs a relatively large amount of light from source130towards the center of output pattern of fixture110. Essentially, central portion152of surface150, and to so extent facets154,156, and158tend to prevent light from LED130from creating a relatively high intensity “hot spot” at the center of lens140by directing some light away from the central axis118, and thus away from the center of the output pattern of lens140. On the other hand, facets161-168tend to direct light back towards central axis118, or towards the center of the output pattern. However, since they are radially lateral of axis118, they tend to create an output that appears like concentric rings of higher intensity than the intensity at the center portion of lens140. There is still intensity across lens140, but a viewer's eyes perceive higher apparent intensity concentric rings and a lower apparent intensity central portion. This creates a distinctive pattern while removing the apparent central and glare-producing “hot spot” of many conventional tail lights.

Not only is tail light10designed to produce the output pattern characteristics described above, but also to meet or exceed DOT/SAE intensity minimums for such a tail light for all test points in regulatory pattern SAE J2040 (March 2000 Revision) for such lights. However, it tends to attenuate the perceived intensity at and around the middle of lens140to an observer, and accentuates the perceived intensity at outer portions of lens140. Even when light source130is operated to increase intensity for braking or turn signal functions, lens140eliminates the “hot spot” of conventional single light source tail lights but accentuates the intensity around and towards the perimeter of tail light110.

More specifically, the embodiment of tail light110creates an intensity distribution at lens140wherein an observer would observe bright concentric rings towards the outside of lens140and would not see a “hot spot” in the middle of lens140. This presents not only an improvement regarding the distraction potential or glare of a hot spot in the middle, but also provides a unique and aesthetically pleasing visual effects for tail light110. The enlarged depiction of light110inFIG. 3is intended to diagrammatically illustrate the higher apparent intensity more peripheral concentric rings for lens140with the three outermost pairs of concentric broken lines. There is still some intensity at the middle (see innermost pair of concentric broken lines, but not a “hot spot”.

It is to be understood that each facet161-168could produce its own apparent “ring” of light. However, lens140tends to produce a brightest apparent ring near the outside of lens140, and then several smaller rings inside that.

FIGS. 7 and 8Aand B provide more information about the specific output pattern of tail light110. Note the specific concentric ring patterns in the candela plot ofFIG. 7. Candela values are shown by the following colors, with white being highest and black being lowest: red, orange, yellow, light green, green, light blue, dark blue. As can be seen inFIG. 7, the concentric ring around the center of the pattern is brightest; not the center. Thus, the center “hot spot” of state of the art lights is eliminated. There are alternating rings of higher and lower brightness to produce the specific pattern. Note that the brighter rings are not necessarily the same width or equally spaced from each other. InFIG. 7they have varying widths and spacing.

FIGS. 8Aand B are Isolux plots of the output pattern, such as are well-known in the art. Note howFIG. 8Bshows the intensity fall off of the output pattern.

Light source130operates off of 16 volt DC with an energy draw of 350 milliamps. It is rated for 100,000 hours service life. Plug138and its wiring, as well as other circuitry to supply electrical power to LED130, can be industry standard. The entire tail light110can be impact resistant and meet DOT/SAE standards.

Light110accomplishes this operation and functionality in a physical assembly that looks almost identical to a conventional, single source, incandescent, four inch diameter, round, red tail light for such vehicles.

Options and Alternatives

It will be appreciated that the present invention can take many forms and embodiments. The above-described exemplary embodiment is only one example. Variations obvious to those skilled in the art are included within the invention, which is described solely by the claims appended herein.

For example, variations in specific forms, materials, and dimensions, functions, and applications are possible while staying within the scope of the invention. It could be utilized for other automotive light applications, or it could be utilized for other lighting applications. One example would be an interior, non-regulated lighted. It could retain an illumination level that is functional but without a hot spot and the unique perimeter, apparent higher intensity rings.

Additionally the specific profile of surface150of lens140could be varied to alter the areas of higher apparent intensity. They do not necessarily need to be concentric rings.