Vehicle lamps may use a semiconductor light emitting device, such as a light emitting diode (LED) as the light source to provide output light pattern. Typically, LEDs are mounted so the LED emits light generally orthogonal to the output optical axis of the lamp. One example of a vehicle lamp using LED is disclosed in U.S. Pat. No. 10,578,267 by North American Lighting, Inc.
According to one embodiment, a vehicle lamp is provided having a heat sink. The heat sink has a first end mounted to a lamp housing and having a free distal end extending into a light chamber adjacent a central optical axis of the lamp. A light emitting diode (LED) is mounted adjacent the distal end of the heat sink to have a central light emitting axis opposite the optical axis of the lamp. A parabolic reflector is positioned rearward of the heat sink, a parabolic reflective surface extending at an upper and lower solid angle relative to the LED, wherein the upper and lower combined solid angle is greater than a half-paraboloid.
According to one embodiment, a vehicle lamp is provided having a heat sink. The heat sink has a first end mounted to a lamp housing and having a free distal end extending into a light chamber adjacent a central optical axis of the lamp. A light emitting diode (LED) is mounted adjacent the distal end of the heat sink to have a central light emitting axis opposite the optical axis of the lamp. A parabolic reflector is positioned rearward of the heat sink, a parabolic reflective surface extending at an upper and lower solid angle relative to the LED, wherein the upper and lower combined solid angle is greater than a half-paraboloid.
In at least one embodiment, the upper and lower solid angles combine to form a full-paraboloid.
In another embodiment, the upper solid angle and lower solid angle are generally equal.
In at least one embodiment, the heat sink has a plurality of fins extending into the lamp chamber.
In another embodiment, the fins each have at least two conductive surfaces generally extruded parallel to the optical axis and spaced apart so air passing around these two surfaces provides convective heat dissipation from the heat sink.
In at least one embodiment, the parabolic reflector has one or more truncated edges.
In another embodiment, the heat sink is oriented at an angle so the distal end of the heat sink is closer to the reflector.
According to one embodiment, a vehicle lamp is provided having a heat sink extending as a pillar from a periphery of the lamp chamber and having a free distal end. A light emitting diode (LED) is mounted adjacent the distal end of the heat sink along a rear surface of the heat sink. A parabolic reflector is positioned rearward of the heat sink, a parabolic reflective surface extending at an upper and lower solid angle relative to the LED, wherein the upper and lower combined solid angle is greater than π.
In at least one embodiment, the heat sink has a plurality of fins projecting from a forward surface opposite the rear surface.
In another embodiment, the fins are provided on the front surface of the heat sink and extend along a length of the heat sink from the LED to the periphery of the lamp chamber.
In at least one embodiment, the parabolic reflective surface is a free form surface that reflects the light generally parallel to the optical axis of the lamp.
In another embodiment, the heat sink is visible through a forward opening of the lamp. The LED is not visible through the forward opening.
According to one embodiment, a vehicle lamp is provided having a heat sink. The heat sink has a first end mounted to a lamp housing and having a free distal end extending into a light chamber adjacent a central optical axis of the lamp. A light emitting diode (LED) is mounted adjacent the distal end of heat sink to have a central light emitting axis opposite the optical axis of the lamp. A parabolic reflector is positioned rearward of the heat sink, a parabolic reflective surface extending at an upper angular sweep above the LED and a lower angular sweep below the LED.
In at least one embodiment, a light shade to block a portion of the light from the LED is integrally formed in the heat sink.
As required, detailed embodiments of the present invention are disclosed herein; however, it is to be understood that the disclosed embodiments are merely exemplary of the invention that may be embodied in various and alternative forms. The figures are not necessarily to scale; some features may be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention.
Current LED reflector designs for vehicle forward lighting are built around the concept of placing an LED at the parabolic focus of a reflector. The LED emits light orthogonal to the optical axis with the circuit board and heat sink resting in the horizontal plane. This only allows for half of a paraboloid to be used to collect light as the board and heat sink cut the paraboloid. This limits efficiency and necessitates performance lamps to have either vertically expansive reflectors (to improve efficiency) or to use multiple reflector cavities (more LEDs, larger heat sink). Both cases are problematic as lamp packaging conditions typically inhibit reflector geometry and increasing the number of cavities typically leads to higher cost, diminished efficiency, a poor thermodynamic environment, increased glare, and the need for design restriction to prevent cavity “cross-talk”, in which and LED from one cavity is able to shine light upon facets from an adjacent cavity (glare concern).
A circuit board 40 is mounted to the heat sink 12. The circuit board 40 is mounted on the rearward side of the heat sink. A light emitting diode (LED) 22 is mounted to the rearward side of the circuit board adjacent to the distal end of heat sink and positioned to have a central light emitting axis 24 opposite the optical axis 20 of the lamp 10. The LED 22 emits a hemisphere of light which has the central light emitting axis 24 which is orthogonal to the surface of the LED 22. The LED's central light emitting axis 24 intersects the LED 22 at a LED focal point 42. LEDs may also be directly mounted to the heat sink, eliminating the need for the circuit board.
The heat sink 12 is formed of a thermally conductive material such as aluminum or magnesium so that the heat generated by the LED 22 is transmitted to the adjacent board 40, which then transmits the heat to the adjacent heat sink 12. In the event of direct-mounted LEDs to the heat sink 12, heat transfer would be directly from LED to the heat sink material.
A parabolic reflector 26 is positioned rearward of the heat sink and has a parabolic reflective surface 28 extending at an upper and lower solid angle 30, 32 relative to the LED 22. The focal point of parabolic reflector surface 28 aligns with the LED focal point 42. The linear distance between LED focal point 42 and the parabolic reflective surface 28 is commonly known as the focal distance. The light emitted from the LED 22 that is incident on the parabolic reflective surface 28, is reflected such that it changes direction to be parallel to the central optical axis 20. In other embodiments, the optical design may be modified so that the parabola reflective surface aims the light into different patterns.
A boundary line 44 drawn rearward from the LED focal point 42 and parallel to the central optical axis 20 intersects the parabolic reflective surface 28. The three-dimensional measure of the amount of light from the light source 22 that is incident on the parabolic reflective surface 28 defines the upper solid angle 30 and the lower solid angle 32. The solid angle above the boundary line 44 is an upper solid angle surface 30 and the solid angle below the boundary line 44 is a lower solid angle 32. The parabolic surface 28 is defined by an upper surface 34 and a lower surface 36. As shown in
Because there are no obstructions between the LED focal point 42 and the lower solid angle surface 36, the light that is incident on the lower solid angle surface 36 may be reflected to the central optical axis 20.
By placing the LED in front of, and emitting light back towards the reflector (vehicle aft), a half paraboloid is no longer necessary as the heat sink and LED board won't cut into the reflector surface. In contrast, a full paraboloid and the new LED orientation, provides the same efficiency in a smaller package and make 100% light collection at the reflector an achievable target within a production sized headlamp, while also allowing for longer focal lengths to be used.
Increased focal lengths provide more robust optics for production tolerance and can help provide higher performance IIHS lamps due to improved source image size. Improved image size also helps protect performance in non-optimal vehicle aiming conditions. Improvements to robustness for tolerance provide more design freedom, decrease design time, and reduce part maturation time.
Moving the heat sink from an enclosed area at the edge of the reflector to an open area in front provides a more thermodynamically advantageous condition, allowing for the use of smaller and more cost-effective heat sinks.
Near 100% light collection at the reflector can entirely shield the LED from visibility, eliminating the need for a separate LED shade, thus making the system robust to stray light (FMVSS/ECE glare regulation). This collection efficiency is not possible to achieve with a conventional half paraboloid in the scale of a normal lamp. In the event of packaging constraint such that an LED shade is required, this system more readily allows for shade material to be molded into the heat sink, alleviating the need for an extra part. LED shades diminish efficiency and increase cost but are necessary in many conventional systems to be regulation compliant. Regulation based glare management is one of the largest hurdles in conventional LED reflector design.
The lamp 10 of the present application provides several advantages. By orienting the heat sink 12 and light source in front of the optical components/reflector (rather than top or bottom) and orienting the optical axis of the LED back toward the reflector (rather than along the vertical as in conventional designs), the LED system can utilize a full paraboloid reflector instead of the conventional half paraboloid. The full paraboloid reflector provides improved efficiency over conventional systems. The location of the heat sink 12 also provides improved thermal condition due to new source location.
The lamp 10 is cost effective in comparison to lamps of similar performance because the lamp has fewer cavities with fewer LEDs, a more cost-effective heat sink, and improved maturation timing. The lamp 10 also provides improved performance potential in relation to modern IIHS safety testing and vehicle aim tolerance. The lamp 10 may also be more robust to manufacturing tolerances than conventional systems.
The lamp 10 provides more efficient headlamps with longer focal lengths. The benefits of this efficiency allow for improved performance while simultaneously diminishing production cost and packaging size. Allowing for longer focal lengths improves the reliability of the part to manufacturing and assembly tolerances while also aiding in making lamp performance more robust to IIHS safety testing and vehicle aiming condition.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms of the invention. Rather, the words used in the specification are words of description rather than limitation, and it is understood that various changes may be made without departing from the spirit and scope of the invention. Additionally, the features of various implementing embodiments may be combined to form further embodiments of the invention.
This application claims the benefit of U.S. provisional application Ser. No. 62/849,784 filed May 17, 2019, the disclosure of which is hereby incorporated in its entirety by reference herein.
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