1. Field of the Invention
The present invention relates generally to lens assemblies for light assemblies, and more particularly relates to near field lens assemblies structured for use with a light source, such as a light emitting diode.
2. Background of the Invention
Light emitting diodes (LEDs) are fast becoming the preferred light source for automotive lighting applications, as they consume less power, but still provide light output level that is acceptable for such applications. Near field lenses (NFLs) are used to collect as well as to collimate the light from a LED source. NFLs typically provide high light collection efficiency (approximately 70-90 percent).
In the automotive field, lighting assemblies not only provide a functional aspect, but also contribute to both the aesthetic appearance and brand signature differentiation between various vehicle lines. Some of the new vehicle designs demand more versatile and/or complex packaging space requirements for corresponding lamp assemblies. For example, high aspect ratio openings, such as long narrow rectangular openings for signal lamps, are currently being proposed. Such packaging requirements for vehicle lamps increase the design complexity of the standard optical elements. Although standard NFLs are efficient light collectors and collimators for LED light sources, they generally have narrowly round or square light exit areas and are thus not suitable for exit areas that are more complex and may require higher aspect ratios.
In one aspect, the present invention provides a near field lens for a light assembly that has a light source. The lens comprises a main body of light transmitting material. The main body includes a light-collecting face disposed generally opposite of a,light-emitting face. A side wall joins the light-collecting and light emitting faces. The light-collecting face defines a pocket that receives light from the light source and further includes a radial collimating surface and an axial surface. The radial collimating surface is structured to direct light radially outward from a central axis along a plurality of radial axes such that along each of the radial axes, light is collimated.
In another aspect, the present invention provides a light assembly for an automotive lighting application. The light assembly comprises a LED light source and a near field lens. The near field lens includes a main body of light transmitting material. The main body includes a radial collimating portion having a cross-sectional shape. Extending radially outward from a horizontal axis is the cross-sectional shape of the radial collimating portion. A structure of the radial collimating portion corresponds to a rotational extrusion of the cross-sectional shape about the horizontal axis. The near field lens further includes a pocket which is defined by the radial collimating portion. Light from the LED light source is received by the pocket. The radial collimating portion is structured to direct light radially outward from the horizontal axis along a plurality of radial axes such that along each of the radial axes light is collimated.
2C is a perspective view of the near field lens depicted in
Further objects, features and advantages of the invention will become apparent from consideration of the following description and appended claims when taken in connection with the accompanying drawings.
Detailed embodiments of the present invention are disclosed herein. It is understood however, that the disclosed embodiments are merely exemplary of the invention and that the invention may be embodied in various alternative forms. The figures are not necessarily to scale; some figures may be exaggerated or minimized to show the details of a particular component. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis of the claims and for teaching one skilled in the art to practice the present invention.
The present invention seeks to overcome some of the concerns associated with using NFLs in lighting applications that demand more complex and/or higher aspect ratio light exit areas and related light distribution patterns.
Employing the principles of the present invention is an NFL that includes a radial collimating portion. The radial collimating portion radially directs light in one plane, which corresponds to a wide hemispherical light distribution, while collimating the light in generally a more narrow light distribution in another plane, transverse to the first plane. Thus, an NFL is provided having a relatively high aspect ratio. This light distribution, which is directed and/or redirected towards a light exit area of the NFL, may be further controlled, enhanced or manipulated to create a more complex and/or higher aspect ratio light distribution.
Referring now to the drawings,
The NFL light assembly 10 generally includes a light source 12 and a NFL 13. Preferably, the light source is an LED. The LED radiates light with a specific spectral power distribution that may represent a color temperature. For example, the LED may radiate a blue, a blue-white or a white color temperature light. Moreover, the LED may radiate light spherically, hemispherically or some fractional portion thereof. Other suitable light sources known to those skilled in the art may also be used.
Referring to
The main body 14 includes a radial collimating portion 16 disposed about a central axis X. As seen in
A light collecting face 19 defines a pocket 20 in the radial collimating portion 16 that receives light from the light source 12. As such, the light source 12 is positioned on or proximate to the central axis X and in the pocket 20 opening.
The radial collimating portion 16 is configured to direct light radially outward from the central axis X along an infinite number of radial axes R, thereby defining a radial light distribution 23 transverse to the central axis X (See
The light collecting face 19 is further comprised of a radial surface 30 located between opposed inner axial surfaces 32, 34. The first and second axial surfaces 32, 34 generally extend outwardly from the horizontal axis 18. The radial surface 30 extends between the inner axial surfaces 32, 34. The radial surface 30 is curved, outwardly convex relative to the light source 20, so as to refract light such that along each X-R plane the light is collimated. The inner axial surfaces 32, 34 are shaped and positioned relative to light source 20 to respectively refract light towards outer axial surfaces 26, 28, which extend generally outward from the central axis X. Preferably, the first and second outer axial surfaces 26, 28 are free form surfaces that redirect light via the principles of total internal reflection such that along each X-R plane the light is collimated.
The radial collimating portion 16 also has a light-emitting face 36, extending generally between the first and second outer axial surfaces 26, 28 and disposed opposite the light-collecting face 30. The shape of the outer light-emitting face 36 is structured to permit light to pass directly through the face 36 and defines the exit opening of the light assembly 10. For example, the outer light-emitting face 36 may have a shape corresponding to an outer perimeter surface of a circular disc, centered about the horizontal axis 18 and transverse to the plurality of radial axes 22.
Referring to
In this embodiment, the main body 114 has a cross-sectional shape (see
The extended portion 138 directs light towards the light-emitting face 136 while maintaining collimation of light along each of the X-R planes. The face 136 may be shaped and positioned to permit light to pass directly through the face 136 without any significant refraction. For example, the light-emitting face 136 may have a shape corresponding to the outer perimeter surface of a circular disc, centered about the central axis X and transverse to the plurality of radial axes R, so as to minimize refraction of light. Alternatively, the face 136 may be shaped and positioned, for example at an incline to the radial axes 22, to redirect or reflect light angularly relative to the radial axes 22, where light may be permitted to exit through another location of the NFL 113.
Referring to
The side surfaces 242, 244 are preferably parabolic in shape so as to reflect light directed along the lateral most axes R (via TIR) toward the light emitting face 236 such that the reflected rays are collimated with respect to each other in the Z-R plane parallel to axis 252 and are perpendicular to the light-emitting face 236. At the face 236, the reflected rays are emitted from the NFL 213 without substantial refraction and are therefore substantially collimated.
Light rays along in inner most axes R will not impinge on the side surfaces 242, 244. Rather, these light rays will interact with the central opening 248. The central opening 248 has a collimating face 250 extending along the central axis X. The collimating face 250 is outwardly convex (relative to the central axis X) and shaped to refract and collimate light received along the innermost axes R. The refracted rays then pass through the central opening 248, through a planar and perpendicularly oriented face 254 (cooperating to define the central opening 248), and out of the NFL 213 through the light-emitting face 236. Thus, light exiting the NFL 213 is collimated in two planar.
In another embodiment, shown in
As noted above, the light-emitting face 236 is structured to permit light to pass directly there-through and to define an exit opening for an NFL 213. The exit opening defined by face is preferably oriented transverse to the longitudinal axis 252 so as to minimize the refraction of light and may be rectangularly or otherwise shaped.
Referring to
Referring to
As a person skilled in the art will readily appreciate, the above description is meant as an illustration of implementation of the principles of this invention. This description is not intended to limit the scope or application of this invention and that the invention is susceptible to modification, variation and change, without departing from the spirit of the invention as defined in the following claims.